RU2012087C1 - Magnetostatic device for beam convergence of color cathode-ray tube - Google Patents

Abstract

FIELD: TV equipment. SUBSTANCE: device has cylindrical yoke. Around its circumference permanent magnets are mounted for movement about radial axes. Each magnet has two poles which are placed in magnet sides which are directed in mutually opposite directions and are on opposite sides about magnet rotation axis. It is possible to make magnets with very little size and weight from magnetic film. EFFECT: decreased cost of device, increased reliability, decreased time for beam convergence. 3 cl, 4 dwg

Description

 The invention relates to elements of color television systems and can be used to reduce the rays of color cathode ray tubes (CRT) in televisions and displays of electronic computing devices.

 Currently, to reduce the rays of a color CRT, multipolar permanent ring magnets are used that are mounted on a cylindrical collar, which, in turn, is mounted on the neck of a tunable CRT.

 To reduce the number of ring magnets, a tape-type magnetostatic device was proposed [1]. In such a device, there is one annular magnet, which is an annular magnetic strip covering the neck of a tunable CRT and magnetized in the process of converting the rays in order to obtain the location of the magnetic poles on the magnetic strip and the distribution of its magnetization, providing the reduction of the rays. Magnetization of the magnetic strip is carried out by applying the appropriate magnetizing current pulses.

 The process of converging rays using such a device is very complex and requires the use of computers to control the supply of magnetizing pulses. Such a device is practically impossible to use to reduce the rays during CRT operation, since it requires complex and expensive equipment to reduce the rays. At the same time, during the operation of a CRT as a result of a change in its parameters, the influence of surrounding magnetic fields, etc., a ray divergence may occur. The inability to reduce the rays during the operation of a CRT is especially negative when used in a display where very high demands are made on the convergence of the rays.

 In addition, despite the possibility of using only one ring magnet to reduce the rays, the mass of such a magnet, which is made of expensive ferrite plastic, remains very large (about 15 g).

 A simpler and more traditional process of converging beams can be achieved by using a device containing several (usually six to seven) multipolar permanent ring magnets eccentrically mounted on a cylindrical collar worn on the neck of a CRT [2]. The reduction of the rays is ensured by turning the eccentrically mounted ring magnets around the axis of the neck of the CRT and moving the clamp with magnets relative to the neck along its axis.

 Such a device does not require the use of sophisticated equipment in the process of converging the rays and allows such reduction when the rays diverge during the operation of the CRT. However, the need to use a large number of eccentrically mounted magnetic rings makes the device rather complicated. The total mass of ring magnets is large (about 60 g), which makes the device expensive because of the need for a large amount of ferrite plastic. The cost of the device also increases due to the need to often change rapidly wearing molds used for the manufacture of ring magnets. The large mass of ring magnets makes the device heavy and reduces its reliability due to an increase in the likelihood of its displacement under the action of shock loads and violation as a result of this information rays. The need to find the optimal position for a large number of ring magnets increases the time required to reduce the rays, which are about 3 minutes.

 The aim of the invention is to simplify the device for converging CRT rays, reducing its mass and cost, increasing its reliability and reducing the time required to reduce the rays.

 The goal is achieved by the fact that in the known magnetostatic device for converting the rays of a color cathode ray tube containing a cylindrical collar on which permanent magnets are mounted, the permanent magnets are placed around the circumference of the clamp with the formation of angular gaps between them and mounted with rotation around axes passing relative to the clamp in radial directions, with each magnet having two opposite magnetic poles located at the edges m facing the opposite sides agnit on opposite sides of the axis of its rotation so that the line connecting the magnetic poles of the magnet runs across this axis.

 The location of the magnetic poles at the edges of the magnet facing the opposite sides is necessary to create a sufficiently high magnetic field strength at the location of the corresponding beam. The location of the magnetic poles on opposite sides of the axis of rotation of the magnet so that the line connecting the poles runs across this axis ensures that the spot formed by the beam on the CRT screen moves along a closed path when this magnet rotates 360 degrees around the corresponding axis. As a result, by choosing the angles of rotation of the magnets, as well as the angular position of the clamp with magnets on the neck of the CRT, in most cases it is possible to quickly and easily reduce its rays. The proposed device has a very simple design, and the magnets used in it are very small in size and mass, which reduces the mass of the device and its cost and increases its reliability. Magnets can be made without molds, which reduces the cost of manufacturing the device.

The number of magnets used in the device may vary. To reduce the rays in CRT displays, it is enough to have two magnets, the angular gaps between the installation sites of which are 180 ± 20 ^° , i.e. from 160 to 200 ^° .

To reduce the rays in television tubes, it is advisable to use four magnets mounted so that the angular gaps between their installation sites are 90 ± 15 ^° , i.e. from 75 to 105 ^° .

 You can use a different number of magnets, for example three, five, etc., placed around the circumference of the clamp with the formation of angular gaps between them.

 In FIG. 1 shows the proposed device with two magnets, worn on the neck of a CRT; FIG. 2 and 3 illustrate the deflection of a CRT beam at different angles of rotation of the magnet; in FIG. 4 shows the proposed device with four magnets.

 In accordance with FIG. 1, a magnetostatic device for converging beams contains a cylindrical clamp 1, on which two permanent magnets 2 and 3 are mounted, arranged around the circumference of the clamp with the formation of angular gaps between them of about 180 °. Magnets 2 and 3 are square plates (see also Fig. 2) made of ferrite plastic, which are glued in the center respectively to the ends of the holders 4 and 5 passing through the holes in the clamp 1. The holders 4 and 5 are mounted for rotation together with the magnets 2 and 3 around axes 6 and 7 extending in radial directions relative to the clamp 1. Each of magnets 2 and 3 has two opposite poles located at the opposite sides of the magnet on opposite sides of the axis of rotation (see also FIG. 2), at The line connecting the magnetic poles of each of magnets 2 and 3 runs across the axis of rotation of this magnet.

 The ends of the clamp 1 are connected using a bolt 8 with a nut 9.

 To reduce the rays of a CRT, the clamp 1 together with magnets 2 and 3 is put on the neck 10 of a custom CRT, in which there are three beams: red, green and blue, and is slightly clamped on it with a bolt 8 and nut 9 so that magnets 2 and 3 were pressed to the surface of the neck 10 of the CRT, but could rotate around the axes 6 and 7 using the holders 4 and 5. This is easy to do due to the elasticity of the ferrite plastic.

 The beam alignment process is illustrated in FIG. 2 and 3. FIG. 2 schematically depicts a partial view along arrow A in FIG. 1 at four different positions of magnet 3, and the position of the CRT beam closest to this magnet; FIG. 3 schematically depicts a view similar to FIG. 1, but without magnet 3, as well as the direction of deviation of the CRT beam closest to magnet 2 at different positions of this magnet.

 In accordance with FIG. 2, the beam 11 is directed from left to right (which corresponds to the direction of the electric current in the beam in the opposite direction), and in accordance with FIG. 3 - towards the observer.

In accordance with FIG. 2a, when the magnet 2 is positioned so that its north pole is facing up and the south pole is facing down, the CRT beam 11 closest to magnet 2 in accordance with the “left hand rule” deviates horizontally towards magnet 2, as shown by the arrow in FIG. . 3a. If the magnet 2 is rotated so that it occupies the position shown in FIG. 2b, the CRT beam will undergo a deflection in the vertical plane twice, since it is crossed twice by the horizontal lines of force of the magnet field, passing from the north pole to the south. In the first case, the beam in accordance with the same rule will deviate downward in a vertical plane, and in the second upward, as shown in FIG. 2b. As a result, when a beam hits the CRT screen, the beam will be deflected upward. This deflection direction is shown by the arrow in FIG. 3b. If the magnet is rotated another 90 ^° to the position shown in FIG. 2c, the beam deviates horizontally away from the magnet, as shown in FIG. 3c. If the magnet is rotated to the position shown in FIG. 2d, the beam deviates vertically downward, as shown in FIG. 3G

 Thus, the rotation of magnet 2 around axis 6 causes the beam closest to it on the CRT screen to move along a closed curve, which, as practice shows, with a square shape of the magnet is close to a circle. The rotation of magnet 2 will also affect the deviation of other rays located at a greater distance from it than the beam 11 nearest to it, but this effect will be much weaker, since the force deflecting the beam decreases in proportion to the square of the distance to the magnet.

 Similarly, by turning the magnet 3 around axis 7, it is possible to control the deflection of another beam, for example, beam 12 (Fig. 3a). If we neglect the influence of the rotation of the magnets on the rays distant from them, then we can imagine that two rays, one of which is closer to one of the magnets and the other to the other, when the magnets are rotated will move along intersecting closed paths, coinciding at the points of their intersection . To combine them with the third ray, it is necessary that its position coincides with one of these intersection points. This coincidence can be achieved by turning the clamp 1 together with magnets 2 and 3 around the axis of the neck of the CRT, as a result of which the dimensions and position of the closed paths of the rays, and therefore their intersection points will change.

In real conditions, the rotation of each magnet will affect not only the beam closest to it, but also the more distant ones. As practice has shown, however, when combining the rays of CRT displays in which one of the rays (green) is always located with high accuracy in the center of the CRT, two magnets are quite enough to quickly combine all three rays on the screen of the CRT. The magnets 2 and 3 do not necessarily have to be set precisely against each other, and satisfactory results are provided at their deviation from the diametrically opposite position by an angle up to ²⁰ °.

 After installing the magnets 2 and 3 in the positions that provide the reduction of the rays, the bolt 8 is tightened with the nut 9, fixing the clamp 1 and magnets 2 and 3 in the required positions relative to the neck 10 of the CRT.

In the process of converging the rays of television tubes, in which the centering accuracy of the green beam is relatively low, the use of two magnets cannot always ensure the reduction of all three rays. In this case, it is advisable to use the device with four magnets shown in FIG. 4. In such a device, it is advisable to place the magnets through angular gaps of 90 ± 15 ^° . Otherwise, the implementation and installation of magnets in a device with four magnets is similar to their implementation and installation in a device with two magnets, shown in FIG. 1.

 The design with four magnets provides more opportunities for changing the position of the rays and the trajectories of their movement during the rotation of the magnets and provides the ability to quickly reduce the rays in all types of CRT televisions and displays.

 The invention allows the use of a different number of magnets, made and installed as described above and placed around the circumference of the clamp with the formation of angular gaps between them. Perhaps, for example, the use of devices with three, five, etc. magnets. A different number and arrangement of magnets may be appropriate, for example, to reduce the rays in tubes having more than three rays.

 The proposed device allows to reduce the rays when using magnets having very small sizes and mass (about 0.3 g each compared to the total mass of magnets in the known device with ring magnets, comprising about 60 g). This saves expensive ferrite plastic and improves the reliability of the device by reducing the inertia of the magnets and the entire device and thereby sensitivity to shock loads. The device has a very simple and lightweight design (its total weight is about 6.3 g), and it is easy to manufacture. An important advantage of the proposed design is the simplicity and low cost of manufacturing magnets, which are made by cutting the tape obtained by pulling through a die without the use of quickly wearing molds. The proposed device can also significantly reduce the time required for convergence of the rays. As tests have shown, this time is about 1 min, i.e., three times less than in a device with ring magnets.

Claims (3)

 1. MAGNETOSTATIC DEVICE FOR REDUCING THE RAYS OF A COLORED ELECTRON BEAM TUBE, comprising a cylindrical collar on which permanent magnets are mounted, characterized in that, in order to simplify the device and reduce its mass and cost, permanent magnets are installed around the collar with angular gaps and with the possibility of rotation around the axes passing through the magnet in the radial direction relative to the clamp, while each magnet has two opposite magnetic poles located at opposite edges m agitation on different sides of the axis of rotation and on a straight line intersecting this axis. 2. The device according to p. 1, characterized in that the angular gaps between the installation of permanent magnets are 160 - 200 ^o . 3. The device according to p. 1, characterized in that the angular gaps between the installation of permanent magnets is 75 - 105 ^o .

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