NL8800884A - Picture display device with magnetisable core - has compensation coil system with core of magnetisable material positioned between display screen and deflection unit - Google Patents

Abstract

The picture display device comprises a display tube having a phosphor display screen at the front end and an electro-magnetic deflection unit mounted around a part of the display tube for deflecting electron beam across the display screen. The unit comprises a line deflection coil and a field deflection coil, and a compensation coil system for generating a magnetic compensation field which is oppositely directed to the line frequency radiation field in a space in front of the display screen. The compensation coil system includes a core means of a magnetizable material which is positioned between the display screen and the deflection unit in a plane parallel to the display screen and which has two diametrically arranged coils each comprising at least one turn.

Description

♦

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PHN 12502 1 N.V. Philips' Incandescent lamp factories in Eindhoven.

Image display device with compensating coils magnetizable core medium.

The invention relates to an image display device comprising a display tube, the rear part of which consists of a cylindrical neck in which there is a device for generating electron beams, while the front part 5 has a funnel shape, the widest part being on the front and contains a display with phosphors, as well as an electromagnetic deflection unit mounted around a part of the display tube for deflecting electron beams over the display, comprising a line deflection coil with two line deflection coil halves and an image deflection coil located on either side of a plane of symmetry, and of a compensation coil system for generating a magnetic compensation field in a space in front of the display opposite to the line frequency radiation field in that area.

Such an image display device with means for compensating (line coil) stray fields is known from EP-A 220 777.

Recently, stricter standards have been introduced for certain types of image display devices, in particular for monitors, with regard to the magnetic interference field they are allowed to produce around them. An important source of magnetic interference fields is the line deflection coil, since, unlike the image deflection coil, it is operated with high-frequency currents (frequencies in the range of 10 to 100 kHz). It is simply not possible to design a properly functioning deflection coil that does not produce stray fields. If one wishes to eliminate the stray field by means of a screen, such a screen is only effective if the CRT-deflection unit combination is also screened on the screen side.

It is true that the external magnetic field of a deflection unit is not very strong; at a distance of 50 cm from the front of a deflection unit for a 110 ° monochrome picture tube, the field strength has already decreased 30 to about 1¾ from the strength of the Earth's magnetic field, but it is the change of the field over time that matters . Field changes can cause interference in other electronic equipment, .8800884 * I * PHN 12502 2 while further investigations are underway to determine the extent to which human health is affected. Today, with the increase of the line frequencies and thus increasingly shorter flyback times, the time derivative of the field of the deflection unit 5 also increases.

The aforementioned patent publication describes the use of a compensation coil system which generates a compensating dipole magnetic field for compensation of the line deflection stray field. This dipole field can be obtained by energizing one coil, the turns of which lie substantially in one flat plane (a "current loop"), which coil has the correct number of turns, the correct surface area and the correct orientation. The energizing can e.g. be done by connecting the compensation coil in series with, or parallel to, the line deflection coil. The compensation field can alternatively be obtained by energizing two "current loops" positioned on either side of the line deflection coil, which current loops have the correct number of turns, the correct surface area and the correct orientation. The energizing can also in that case e.g. are done by connecting the compensation coils formed by the current loops in series with, or in parallel with, the line deflection coil.

Preferably, the compensation coils are large to reduce their energy content.

However, a problem is that in many types of display directions (especially monitors) there is no space to install large coil assemblies in the right place. As a result, relatively small (too small) compensation coils must be used, so that the radiation compensation uses a lot of (line deflection) energy. In addition, the sensitivity of the line deflection coil is adversely affected in case the compensation coil system is connected in series with the line deflection coil. The self-induction then increases.

The object of the invention is to provide measures which make it possible to compensate for the radiation field of the line deflection coil which uses less energy and costs less sensitivity than the known measures.

This task is solved according to the invention in that the device of the type mentioned in the preamble has a compensation coil system. 8800884 * PHN 12502 3 comprising a core means of magnetizable material positioned between the screen and the deflection unit in a plane parallel to the screen. and is provided with two diametrically opposed coils, each comprising at least one winding, 5 coils. (The windings generally lie in planes that are perpendicular to the screen.)

The simplicity of this radiation compensation solution, which relies on the use of a magnetizable material core means comprising a set of core means comprising (= 10 enclosing) toroidal coils or a set of saddle coils, is superior to all known solutions of this problem, which are based on the use of coreless, or air coils. A coil comprising a core of magnetizable material takes up little space and the loss in sensitivity is extremely small, in one case e.g. 5x 15 less than with a known solution using one air coil above and one air coil below the deflection unit.

Toroidal coils are understood to mean coils wound around {part of) the core agent. According to an embodiment of the invention, they are arranged near places where the plane of symmetry of the line coils intersects the picture tube. Saddle coils are understood to mean coils placed on a core portion of the core agent. According to an embodiment of the invention, they are arranged on either side of the plane of symmetry of the line coils.

A preferred form of the device according to the invention is characterized in that the core means comprises a single closed annular core placed parallel to the screen and surrounding the display tube at a position in front of the deflection unit. The use of a closed annular core surrounding the tube and provided with two (saddle-shaped or toroidal) coils has the advantage of great sensitivity.

An alternative is to use a core agent with a separate core part, e.g. a ring segment, or a bar element, for each (toroidal) coil, which can have advantages in winding and mounting.

35 The core parts are in this context especially. positioned so that they intersect the plane of symmetry of the line deflection coil. In one embodiment, the core members are arranged on either side of the .8800S84 <1 PHN 12502 4 funnel-shaped portion of the picture tube, symmetrically to the plane through the axis of the tube that is perpendicular to the plane of symmetry of the line deflection coil.

Core parts with a rod shape have proved very suitable in practice for use. The length of the rod-shaped core parts is preferably at least equal to the largest cross section of the line deflection coil. The rod-shaped core parts may be provided with permanent magnets at both ends to correct any landing influence.

Winding the rod-shaped core parts with coils should preferably take place in such a way that a magnetic field which is as symmetrical as possible is generated when the coils are energized. There are several alternatives to this.

A first embodiment is characterized in that the core parts are provided with coils with a coil winding pattern containing an ascending and a descending winding which cross each other.

A second embodiment is characterized in that the core parts are provided with coils with windings, the winding surfaces of which are at least substantially parallel to the plane of symmetry of the line deflection coil, while the windings are mutually connected by wire pieces extending parallel to the axis of the core parts.

For a favorable effect it is both in the case that the core agent comprises a toroidal core, and in particular, in particular. in the case of using a separate ring segment for each (toroidal) coil, it is important that the projection of the toroidal core or of the segments on the plane of symmetry of the line deflection coil has a size parallel to the display greater than the size perpendicular to the screen.

A further important aspect is that the toroidal core, resp. the core parts, with the associated coils, can be positioned as favorably as possible.

By positioning a certain distance in front of the deflection unit, it can be achieved that the (magnetizable) toroidal core, 35 resp. the core parts, capture as little magnetic flux as possible from the line deflection coil. Although this means that on the one hand there is no shielding effect (the invention is not based on that), .8800834 * PHN 12502 5, but on the other hand there is no substantial influence on the line deflection field and, in particular, there are virtually no side effects on convergence and grid. . In addition, in the case where the compensation coils are saddle type coils, the side effect on landing 5 appears to be minimal.

Within the scope of the invention it is possible to convert the magnetizable toroidal core, respectively. placing the core parts, with the associated coils, in such an axial position that the coils lie in a plane that at least substantially contains the imaginary radiation center of the line deflection coil 10. This means that the imaginary radiation center of the compensation coil system then at least substantially coincides with the imaginary radiation center of the deflection unit. Due to the fact that the diameter of the line deflection coil and the surrounding yoke ring increases in the direction of the screen, the radiation center of the deflection unit does not coincide with its mechanical center, but lies a short distance (a few centimeters) in front the deflection unit (in the picture tube). This means that in the known solutions it is not possible to position the compensation coil or coils such that the radiation center of the compensation coil system 20 coincides with the radiation center of the deflection unit. As a result, the generation of the compensation (dipole) field is associated with the generation of a higher order magnetic field (quadrupole field, six-pole field depending on the chosen configuration). In general, in order to meet the requirements, it is necessary to compensate this higher order field 25 in turn. The latter requires an additional compensation flush system. This problem does not exist with the device according to the invention, because it is possible to remove the toroidal core or. to position the core parts of magnetizable material with the associated compensation coils such that the radiation center of the compensation coil system coincides at least substantially with the radiation center of the deflection unit.

A practical form of connection of the compensation coil system according to the invention is characterized in that the coils have the same winding direction and in operation can be connected to a line frequency current source in such a way that the fields they generate have the same direction.

Some exemplary embodiments of the invention will be explained with reference to 8800884 4 4 PHN 12502 6.

Figure 1a shows a perspective view of a picture display device with a picture tube provided with an electromagnetic deflection unit with a compensation coil system; Figure 1b schematically shows the line deflection coil of the electromagnetic deflection unit with the compensation coil system of Fig. 1a;

Figure 2a schematically shows a rear view of a picture tube on which a compensation coil system according to the invention is arranged;

Figure 2b schematically shows a coil-tube combination in longitudinal section with a compensation coil system according to the invention;

Figure 3 schematically shows a tube-coil combination in longitudinal section with a conventional compensation coil arrangement; Figures 4a, 4b and Figure 5 show toroidal compensation coil arrangements according to the invention;

Fig. 6 shows a compensation coil arrangement according to the invention with saddle coils and

Fig. 7 shows a saddle coil suitable for use in the arrangement of FIG. 6.

Fig. 8 and 9 show compensation coil arrangements with rod-shaped core parts which are coil wound in a first and a second way.

Fig. 10 shows an electrical diagram for a possible way of connecting the compensation coil system according to the invention.

Figure 1a shows a perspective view of a deflection unit-display tube combination placed in a cabinet 1 and which, in the context of the invention, is provided with a compensation coil system 3.

For the sake of clarity, all details which are not important for an understanding of the invention have been omitted.

The display tube 4 has a cylindrical neck 5 and a funnel-shaped part 6, the widest part of which is located at the front of the tube and contains a screen (not shown).

The display contains phosphors that, when hit by electrons, light up in a predetermined color. In the rear portion of the neck 5 is an electron gun system 880 0884 PHN 12502 7 7 (shown schematically). Near the transition between the neck 5 and the funnel-shaped part 6, a schematically indicated electromagnetic deflection unit 8 is arranged on the tube, which includes a line deflection coil 9a, 9b (figure 1b) for deflecting the electron beams in horizontal direction x . As schematically indicated in figure 1b, the line deflection coil 9a, 9b generally consists of of two saddle-shaped coil halves that lie on either side of a symmetry plane (the x-z plane). A sawtooth-shaped current with a frequency between 10 and 100 kHz, for example with a frequency of about 64 kHz, is passed through here in operating state. In general, the line deflection coil 9a, 9b is surrounded by an annular core element 10 of soft magnetic material, the so-called yoke ring, which is also schematically shown in figure 1b.

Assuming that the radiation field of a line deflection coil with yokering is the same size but opposite to that of a coil without yokering, the line deflection coil can be conceived as a circuit with a given magnetic moment for long distances.

The field B0 in the radiation center of a line deflection coil without yokering can be calculated at about 30 Gauss. The field of a practical deflection coil with yokering is approximately double.

The way in which this radiation field is compensated for with a conventional solution is shown with reference to Fig. 3.

Figure 3 schematically shows a picture tube 20 with a neck-sided electron gun 21 and a front-side screen 27. On the outer surface of the picture tube 20 a deflection unit is provided, of which only the line deflection coil 26a, 26b is shown schematically.

Figure 3 further shows a deflection unit with two sets of 30 compensation coils, a "horizontal" set 22, 23 for substantially generating a dipole compensation field and a "upright" set 24, 25 for substantially generating a four pole compensation field. . By choosing the number of turns of the upright set differently from the lying set and the flow directions as well as the dimensions of the lying set and the upright set well, a considerable field reduction at distances of about 50 cm can already be realized turn into. Attn. Choosing the directions of flow correctly means in particular that when the suppression coil system is energized, the currents in the horizontal parts run in the same direction as the currents in the corresponding (axial) parts of the line deflection coils and that the currents in upright parts run in a direction opposite to the direction of the 5 corresponding (transverse) parts of the line deflection coils.

The operation of the coil arrangement of figure 3 is made clear by the following. The disturbing field of a line deflection coil 26a, 26b can be broadly interpreted as a dipole in the tube 20 (= current loop 26 '). In other words, because the diameter 10 of the line deflection coil 26a, 26b increases towards the display 27, the center of the radiation field of the line deflection coil is in front of the line deflection coil. The compensation is done with the coils 22 and 23 which are arranged symmetrically with respect to the symmetry plane of the line deflection coil 26a, 26b. However, as a result of the distance Δ Y1 between the 15 coils 22 and 23 a 6-pole component is also created, and as a result of the distance Δ Z also a 4-pole component. If the coils 22, 23 are pushed forward (to reduce Δ Z and thus the 4-pole component), ΔΥ ^ must increase and thus the 6-pole component increases. If ΔΥ ^ is kept small, the 6-pole component can be reduced somewhat by increasing the diameter of the coils 22 and 23, which means that Δ Z must increase, because the coils cannot penetrate the pipe . The two vertical coils 24 and 25 mainly generate a 4-pole, proportional to the size of the coils, the current through the coils and the distance Δ Υ £. By a good interplay between coil sizes and current strengths, the 4 and 6 poles can be neutralized, so that the final effect of the compensation coil arrangement is outwardly a dipole field which is opposite to the radiation dipole field of the line deflection coil.

An important drawback is therefore that the radiation center of the conventional compensation coil arrangement, both along the y-axis and along the z-axis, does not coincide with the (imaginary) radiation center of the line deflection coil.

This drawback has been recognized in the present invention, which has led to the design of a completely new compensation coil arrangement. In one embodiment, two compensation coils 11, 12 have been used which comprise a core means 13 of magnetizable material (Fig. 1b, 2a, Fig. 2b). In the arrangement 8800884 PHN 12502 9 shown in Fig. 1b, the coils 11, 12, each of which need only few turns (eg, less than 10), are wound toroidally on a single annular core 13, but as previously indicated, it may be beneficial to use saddle type compensation coils. The core 13, which is of the same material, e.g. MnZn ferrite, can be made if the toroidal core of a deflection unit is placed some distance (e.g. a few cm) in front of the deflection unit 8 with line deflection coil 9a, 9b and yokering 10 to influence the (line) deflection field as little as possible. Thus, the core 13 should preferably not abut directly on the front side conductor portions of the line deflection coil 9a, 9b. The winding direction and excitation of the coils 11, 12 is such that they generate magnetic fields H, H 'having the same orientation.

Fig. 2a shows a picture tube, such as the picture tube 2 from fig. 1, with a compensation coil arrangement according to the invention in rear view, and fig. 2b in top view. The core 13 with the coils 11 and 12 can be positioned (in axial directions, or z direction) such that the radiation center of the compensation coil system coincides at least substantially with the radiation center of the line deflection coil.

The effect of the compensation coil system according to the invention is beneficial if the coils are provided with an annular core 14 (fig. 4a), or with toroidal segments 15a, 15b (fig. 4b) which have a dimension in the x-direction larger than their size in the z direction. The use of toroidal core segments as shown in Figure 4b may in itself lead to easier mounting on the cathode ray tube.

Fig. 5 shows a toroidal core 16 with two very flat compensation coils 17, 18 which lie almost entirely in the x-z plane, the plane of symmetry of the line coils. The windings of the coils 30, 17, 18 lie in planes which are substantially parallel to the x-z plane.

Fig. 6 shows a core means in the form of a disc-shaped toroidal core 20 provided with an opening 19, comprising two saddle coils 21, 22 of the one shown in FIG. 7 is provided which lie on either side of the x-z plane, the plane of symmetry of the line coils. The windings of the coils 21, 22 lie in planes which are substantially transverse to the screen parallel to the x-y plane.

.8800884 ΡΗΝ 12502 10 η

Fig. 8 shows a core means 23 containing two rod-shaped core members 24, 25 disposed on either side of a funnel-shaped display tube section 26, symmetrical to a plane V passing through the display tube axis 27 and perpendicular to the symmetry plane H of the line deflection coil (not shown). In a particular application, the rod-shaped core members 24, 25 had a length of 120 mm and a diameter of 5 mm and were made of 4C6 ferrite. Bar lengths from 10 to 20 cm were found to be e.g. be suitable in practice. Coils 28, 29 with a limited number of turns (in connection with the self-inductance) are provided on the core parts 24, 25, which in this exemplary embodiment extend over the major part of the length of the core parts 24, 25.

In order for the coils 28, 29 (connected in series in this embodiment) to generate as symmetrical a field as possible when energized, they have a winding configuration with an ascending and a descending winding that cross each other. In one application, each wrapper had eight turns. In practice, wrappers with from six to ten turns turned out to be suitable. In the figure, the windings start and end at the ends of the core parts, but the invention is not limited thereto. A practical way of wrapping is e.g. to wrap up from the middle, then all the way down, and finally back up to the center.

An alternative to generate as symmetrical a field as possible is illustrated with reference to Fig. 9. The rod-shaped core parts 30, 31 in that case are provided with coils 32, 33, the turns of which are substantially parallel to the plane of symmetry H of the ( line deflection coil (not shown), while the windings are interconnected by wire pieces parallel to the longitudinal axes of the rod-shaped core parts 30, 31.

To correct any landing impact, the rod-shaped core members may be provided with permanent magnets 34, 35 and 36, 37 at their ends as shown in FIG. 9.

Another possibility to reduce the landing influence when using compensation coils wound on rod-shaped core parts is to add a configuration with two diodes. The compensation coils are then in principle connected in parallel to each other, as is shown schematically in Fig. 10, in which two parallel-connected line deflection coils 41, 42 are connected in series 880 0884 PHN 12502 11 with two parallel-connected compensation coils 43, 44. Using e.g. diodes 45, 46 are made to ensure that when the electron beams are deflected to the "right" on the display the line deflection current is mainly conducted through the "left" compensation coil 43, and vice versa.

t8800884

Claims (15)

1. Image display device provided with a display tube, the rear part of which consists of a cylindrical neck in which there is a device for generating electron beams, while the front part has a funnel shape, the widest part being at the front and a screen with Phosphors, and of an electromagnetic deflection unit mounted around a portion of the picture tube for deflecting electron beams across the display, comprising a line deflection coil having two line deflection coil halves disposed on either side of a plane of symmetry and an image deflection coil, and of a compensation coil system for generating a magnetic compensation field, which in a space at the front of the screen is opposite to the line-frequency radiation field in that area, characterized in that the compensation coil system comprises a core means of magnetizable material which is between the screen and the screen unit is positioned in a plane parallel to the display and is provided with two diametrically opposed coils, each comprising at least one turn. 2. Device according to claim 1, characterized in that the two coils are each of the toroidally wound type and are arranged near places where said plane of symmetry intersects the picture tube. 3. Device according to claim 1, characterized in that the two coils are each of the saddle type placed on a core part and arranged on either side of said symmetry plane. Device according to claim 1, 2 or 3, characterized in that the core means comprises a single closed annular core placed parallel to the screen and surrounding the display tube at a position in front of the deflection unit. Device according to claim 2, characterized in that the core means comprises two core parts which intersect the plane of symmetry of the line deflection coil and in that each coil is wound individually around a core part. 6. Device according to claim 5, characterized in that the core parts are arranged on either side of the funnel-shaped part of the picture tube, symmetrical with respect to the plane through the axis of the tube which is perpendicular to the plane of symmetry of the line deflection coil. .8800884 PHN 12502 13 Device according to claim 6, characterized in that the core parts are ring segments. Device as claimed in claim 6, characterized in that the core parts are rod-shaped. Device as claimed in claim 8, characterized in that the core parts are provided with coils with a coil winding pattern containing an ascending and a descending winding which cross each other. 10. Device as claimed in claim 8, characterized in that the core parts are provided with coils with windings, the winding surfaces of which are at least substantially parallel to the plane of symmetry of the line deflection coil, while the windings are mutually connected by parallel to the axis of the core parts extending thread pieces. 11. Device according to claim 4 or 7, characterized in that the projection of the toroidal core or toroidal segments on the plane of symmetry of the line deflection coil has a dimension parallel to the screen that is larger than the dimension perpendicular to the screen. 12. Device as claimed in claim 1, characterized in that the core means lies in a plane which at least substantially contains the imaginary radiation center of the line deflection coil. 13. Device according to claim 1, characterized in that the coils of the compensation coil system have the same winding direction and can be connected in operation to a line frequency current source such that the fields they generate have the same direction. Device according to claim 8, characterized in that the rod-shaped core parts are provided at both ends with permanent magnets for correcting landing errors. 15. Device as claimed in claim 8, characterized in that a diode configuration is electrically connected to the coils arranged on the rod-shaped core parts, such that in operation mainly the coil furthest from the deflected beams is energized. .8800884