FI70357C - DETAILED DESCRIPTION OF THE ACCOUNTING MEASURE - Google Patents

Description

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6 (11 * UTLÄGGNINGSSKRIFT 7035 7 1¾¾¾ C (45) Patent iayönactty pÄ / äJ v 'Patent meJGelat 15 09 1000 (51) Kv.lk.' / Int.CI. * H 04 N 9/29 (21) Patent application - Patentansökning 800394 (22) Application date - Ansökningsdag 08.02.80 (H) (23) Start date - Giltighetsdag 08.02.80 (41) Has become public - Blivit offentlig 1 7.08.80

Patent, and the National Board of Registration Date of display and publication. - __ ns

Patent and registration authorities '' Ansökan utlagd och utl.skriften publicerad zö.Uz.ob (32) (33) (31) Privilege claimed - Begärd priority 1 6.02.79 USA (US) 012810 (71) RCA Corporation, 30 Rockefeller Plaza , New York, New York 10022, USA (72) John Clarence Cooper, Lititz, Pennsylvania, USA (74) Oy Kolster Ab (54) Tilted unit-structured field removal coil arrangement -Snedställt enhetligt spolarrangemang för fä1 taviägsning This invention is directed to an arrangement for removing a magnetic field from color picture tubes having magnetic shields using unit design field removal coils in an inclined or oblique position.

Color television display is often implemented using perforated plate tubes. In such tubes, a number of electron beams are directed from slightly different starting points towards an image surface coated with fluorescent phosphor materials. These phosphorous substances are grouped into triplets or groups, each part of which fluoresces a different primary color when illuminated with an electron beam. Each part of each triad is made to operate on the basis of a single electron beam in this set by means of a perforated plate. This perforated plate is a thin conductive shield with a series of perforations precisely positioned relative to each of the triads of color phosphor materials. This perforated plate ideally allows the illumination of a phosphorus substance of a given color using only one electron beam coming from a particular location. Thus, using three electron beams from slightly different starting points, each of the triplet color phosphor remains pure, i.e., it is illuminated by only one electron beam, and color variation can be realized by appropriate electron supply source control.

In the past, color TV screens were sensitive to the effects of the earth’s magnetic field. The magnetic field passing through the picture tube bends the electron beams away from their intended paths and changes the apparent starting point of the electron beams entering the perforated plate in a way that depends on the orientation of the picture tube relative to the earth's magnetic field, thus degrading color purity. Previous attempts to remedy this problem have used field neutralizing coils, as described in U.S. Patent No. 2,921,226, issued January 12, 1960, to Vasilevskis. In the field neutralization arrangement, direct current is applied through one or more windings arranged around the picture tube so that the ground field is balanced to zero or neutralized. This adjustment, and the necessary readjustment if the television is moved to a new location, requires an expert to perform.

Another way to remedy the problems caused by the earth's magnetic field of color purity involves the use of magnetic shields. In such an arrangement, a hollow shield in the shape of a truncated cone surrounds the area through which the electron beam passes before reaching the perforated plate and the image surface. The high permeability of this shield diverts the extra magnetic field away from the electron beam. However, it has been found that such a magnetic shield was able to become magnetized and thus, when magnetized, it itself disturbed the purity of the colors. Magnetic field removal arrangements were then designed to demagnetize this shield and shadow mask. This removal of the magnetic field is accomplished by applying an alternating current of initially high amplitude through one or more windings arranged around the perforated plate and the magnetic shield, as described in U.S. Patent No. 2,962,621, issued November 29, 1960 to Fernald.

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The magnitude of the alternating current is then gradually reduced to zero, whereby the magnetization of the shield and the perforated plate decreases. A coil placed along the circumference of the perforated plate, as illustrated in the above-mentioned invention, tends to provide a relatively small magnetic field near the center of the perforated plate and the image surface. Thus, it requires effective field removal using such windings, currents that can be harmfully large.

In order to increase the magnetic field through the magnetic shield and thus the image surface without excessive coil currents, arrangements such as those described by Norley in U.S. Patent No. 3,322,998, issued May 30, 1967, and Matsushima et al., U.S. Pat. No. 3,872,347, issued March 13, 1975. These Norley and Matsushima arrangements used a pair of coils symmetrically over a picture tube, each coil having a certain portion located along the perimeter line of the perforated plate and a portion extending in the direction of the neck of the picture tube. These two winding arrangements provide a magnetic field whose lines are located transversely or perpendicular to the longitudinal axis of this tube. This "transverse to the axis" magnetic field removal arrangement using a pair of coils provides efficient magnetic field removal. However, these two windings require additional installation work when compared to a single winding and their interconnection may result in an incorrect connection. In addition to this, the arrangement of two windings tends to require a longer conductor length than the type of one winding and may, due to the field of the deflection coil unit, cause currents which interfere with the purity of the colors.

It is desirable to have a field removal arrangement that uses unit-structured windings that require only a relatively short conductor length and provides a field removal operation that substantially corresponds to a two-winding system combined with the simplicity of a short conductor length in a single winding type.

The present invention thus relates to a demagnetizing apparatus for a color television picture tube, the conical portion comprising an expandable portion with small and larger ends, a front end portion arranged at a larger end, and a neck concentric with the expanding conical portion 4 70357 and a neck connected to the smaller end of the portion. further comprising a perforated plate disposed within the cone adjacent the front plate portion and a device for electron beams fitted to the neck portion, an expandable magnetic shield having a smaller and larger end disposed adjacent to a portion of the further expanding cone portion, and a single magnetic removal coil with a switching device alternating current to remove magnetism from the hole plate and magnetic shield.

According to the invention, this single magnetic removal coil surrounds the expanding conical portion and is inclined with respect to the axis of this conical portion so that the first portion of the coil circumference is above the region of the cone adjacent the larger end portion of the cover and the second coil circumferential portion the opposite portion is located adjacent to the region of the cone that is near the portion of the smaller end of the cover and farther from the axis than the periphery of the opening at the smaller end of the cover.

The invention will now be described in more detail with reference to the accompanying drawings, in which Figures 1a and Ib illustrate perspective views of a picture tube according to the invention with field removal arrangements, Figures 2a and 2b illustrate corresponding rear and side views of the magnetic field distributions related to the invention and Figs. 4a and 4c illustrate prior art magnetic field distributions, Fig. 5 is a partial pattern diagram including a block portion, a diagram and a pattern portion illustrating the arrangement of the present invention when used in a television receiver.

In Figures 1a and Ib, a picture tube, generally indicated at 10, includes a sheath consisting of three different parts. The truncated cone or pyramid-shaped portion 12a of the sheath 70357 is connected at a small end of the truncated cone to the neck portion 12b in the sheath. The flat image surface portion 12c closes the larger end of the truncated cone portion 12a. The base 14 at the end of the neck portion 12b farther from the portion of the truncated cone supports pins to make connections to the electron gun assembly mounted within the neck portion 12b. The connection 16 of the high voltage anode or extreme anode is located on the surface of the truncated cone portion 12a. The magnetic field removal coil, generally designated 20, is located on the outer surface of the sheath 12. The winding 20 has a substantially rounded triangular shape. One branch 20a of the winding 20 is located adjacent the circumferential line of the junction of the image surface 12c and the frustoconical portion 12a of the sheath. The other arms 20b and 20c of the coil 20 form a peak extending in the direction of and around the junction of the conical portions of the neck and sheath. A pair of conductors 22 are taken from the winding 20 to be connected to a supply source, not shown, by means of which a variable-amplitude current is passed through the winding 20 to remove a magnetic field.

Figures 2a and 2b illustrate rear and side views of the arrangement of Figures 1a and Ib, respectively. The rear view of Figure 2a illustrates the somewhat rectangular outline of the larger end of the truncated cone portion, which is common in currently used picture tubes. However, the neck portion is round, as seen in this rear view, to make it easy to install deflection coil units and other neck components.

A top cross-sectional view of the image tube 10 in Figure 3 illustrates the phosphor surface 330 adjacent the inner surface of the sheath image surface 12c. The perforated plate 332 is mounted close to the phosphor surface 330 by means of mounting lugs 334 and 336. Mounting lugs 334 and 336 also support a hollow magnetic shield 338 formed of a magnetically conductive material. Most preferably, the cover 338 has the shape of a truncated cone portion 12a of the jacket of the picture tube 10. Both the large and small ends of the shield 338 are open to allow one or more electron beams to pass from the electron gun structure 340 mounted within the neck portion 12b to the phosphor surface 330.

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The direction of the magnetic field distribution provided by the magnetic field removal coil mounted concentrically with the picture tube is illustrated in a cross-sectional view in Fig. 4a. When testing such an arrangement, the magnitude of the field available for removing the magnetic field in the center of the image surface 332 was 0.2 gauss, the coil providing a maximum value of 20 gauss. This coil also provided a Gaussian intensity of between 0.3 and 0.6 at the edge of the small or inlet opening of the magnetic shield 338.

In contrast, the arrangement according to the invention has more of a magnetic shield 338 as its core part and provides a distribution of the magnetic field in some way as shown in Fig. 4b. The center of the image surface is in the range of higher field strength. Using a magnetic field removal coil which provides the same maximum field strength as in the case of Fig. 4a, the magnetic field removal field in the center of the image surface was 0.5 gauss, which is almost double the previously known arrangement. The corresponding field strengths at the inlet end of the magnetic shield 338 were 7.5 gauss on the side closest to the winding, 1 gauss on the side furthest from the winding, and 4 gauss on the other two sides thereof. Thus, the field strengths available for magnetic field removal are much higher in the arrangement of the invention than they are in the arrangement of Figure 4a when the coils have the same number of ampere turns.

Figure 4c illustrates the magnetic field distribution associated with two coil arrangements as described in the aforementioned U.S. Patents 3,872,347 and 3,322,998. In the arrangement of Figure 4c, the combined action of a pair of coils provides a substantial magnetic field flux in the transverse direction of the image tube axis. At the end of the tube on the side of the image surface and the perforated plate, the lines of the magnetic field are parallel in the direction of the perforated plate and tend to have a uniform intensity across the center of the perforated plate. The magnetic field removal provided by the arrangement according to the invention substantially corresponds to that obtained by the two-coil arrangement according to Fig. 4c in that it provides magnetic field removal for the inner magnetic shield, as well as for the perforated plate and the image surface. The magnetic field removal arrangement of the invention is less expensive because it requires less conductor length than either the single coil arrangement of Figure 4a or the dual coil arrangement. The arrangement according to the invention is easier to assemble than a two-winding system and cannot be connected incorrectly.

Figure 5 illustrates a circuit with which a magnetic field removal winding can be supplied using an alternating current which initially has a large amplitude which decreases substantially to zero amplitude. In Figure 5, a part of the television set includes a plug 510 suitable for connection to an AC mains supply. Switch 512 and fuse 514 connect the supply network power converter 516 over the primary winding 516a. The secondary winding 516b of transformer 516 provides alternating current used in the power supply illustrated in block 518 to power the remainder of the television receiver illustrated in block 520. The AC mains supply is also thermally connected to terminal 220 a positive temperature coefficient so that the resistance value of the thermistor is low at room temperature and increases as the temperature increases.

At room temperature, the resistance of thermistor 530 is low.

When switch 512 is closed to provide power to the television receiver, power is applied through transformer 516 to power supply 518 to power the receiver. At the same time, an AC voltage is applied across the series connection of the thermistor 530 and the coil 220. Since the resistance value of the thermistor 530 is initially low, a relatively large alternating current flows through the winding 220. The flow of current through the thermistor 530 causes the thermistor to heat up and its resistance begins to increase. Increasing resistance reduces the flow of current from the input voltage and partially compensates for the reduced power loss in the thermistor with reduced current. The temperature of the thermistor continues to rise, which results in a rapid decrease in current up to a small limiting value when the resistance value of the thermistor is maximized. A circuit arrangement using thermal power resistors is described in U.S. Patent 4,024,427 to Belhomme, issued May 17, 1977.

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Although the described arrangement uses an internal magnetic shield, one skilled in the art will recognize that the principles of the present invention are equally applicable to an image tube equipped with an external shield.

Claims (6)

1. A color television image tube removal device (10), comprising a condenser (12a) having a portion which expands and has a small end and a larger end, with a front plate (12c) disposed adjacent to the larger end and a neck (12b). ) which is coaxial with the condenser which expands and corrugated with the smaller end of this portion, further a shadow mask (332) provided in the condenser adjacent to the front plate and a device (340) in the neck portion for producing electron beams, further a magnetic shield (338) expanding and disposed adjacent to a section of the expanding condenser which has a smaller and a larger end, and a single de-magnetization coil, which can be measured by a coupling device with a variable alternating current to de-magnetize the shadow mask and the magnetic shield, characterized in that the only de-magnetization coil (20,220) surrounds the condenser (12a) which expands and slopes relative to the axis of this condel means that a first section (220a) of the coil's circumference is above a cone area adjacent to a portion of the larger end of the screen and a second section of the coil's circumference located diametrically opposite the first section (20a) is adjacent a cone area which is located near a portion of the smaller end of the screen (338) and further away from the shaft than the periphery of the aperture at the smaller end of the screen. 2. Demagnetizing device according to claim 1, characterized in that the first coil section (20a) lies on a cone area near an upper part of the larger end of the screen and the second coil section lies on a cone area which is close to a lower part of the smaller end of the screen. 3. Demagnetizing device according to claim 1 or 2, characterized in that the condenser which expands essentially has the shape of a truncated cone and that the shape of the magnetic shield is essentially a truncated cone. 4. Demagnetizing device according to claim 1 or 2, characterized in that the expanding condel and the magnetic shield each have substantially the shape of a truncated pyramid and that the shadow mask is substantially rectangular.