FR2689679A1 - Device for deflecting electron beams for self-converging cathode ray tubes and corrected in geometry. - Google Patents

Abstract

Device for the deflection of electron beams for cathode ray tubes whose horizontal deflection coils are comprised of a main winding (21) and an auxiliary winding (22) situated in front of the main winding and wherein the current circulates in a direction opposite (31) to the direction of circulation of the current (30) in the main winding. This type of deflection device allows, locally, to amplify the harmonic of rank 2 of the field created by the winding and to decrease the amplitude of the harmonic of rank 4. Thus, the deflection device of the invention will be corrected in geometry North/South while preserving the convergence of the beams throughout the surface of the screen. Said device is particularly adapted to tubes whose image screen has a pronounced radius of curvature.

Description

DEVICE FOR DEFLECTION OF 8 ELECTRON BEAMS
FOR CATKODIOUI RAY TUBES
SELF-CONVERGING AND CORRECTING IN GEOXETRY.

The present invention relates to a device for deflecting electron beams from an electron gun with three beams in line with a cathode ray tube comprising a substantially flat screen panel.

In cathode ray tubes using an electron gun with three coplanar beams corresponding to the three primary colors Red, Green, Blue, the deflection device, also called deflector, has the function of deflecting the beams so as to make them explore the whole surface of the tube screen to generate the images and to ensure the convergence of these beams during all the exploration.

Under the action of uniform horizontal and vertical deflection fields, the volume swept by the electron beams is a pyramid whose apex coincides with the deflection center of the deflection device and whose intersection with a screen surface of large radius of curvature determines a figure with a defect in geometry called a cushion. This geometrical deformation of the image is all the greater the greater the radius of curvature of the screen of the tube.

The so-called self-converging deflectors generate magnetic fields and astigmatic lines in order to ensure the convergence of the electronic beams at the level of the perforations made in the color selection mask, placed at very close distance from the screen of the tube. The lines of force of the magnetic fields created must then be in cushion for the line field and in barrel for the field field
These magnetic fields modify the NORTH / SOUTH geometry and
EAST / WEST of the image, in particular by compensating for the NORTH / SOUTH cushion deformation due to the flatness of the screen.

 I1 is known, to correct the residual geometrical deformations, to use metal parts extending in front of the deflection device as in the Toshiba patent US4257023, or a series of oriented magnets arranged on the deflection device or close to it, as described in the patent application Videocolor FR8702370, or to reverse the direction of current flow in a part of the line winding as in patent FR2411486. However, none of these devices makes it possible to control the NORTH / SOUTH geometry of the image over the entire surface of a substantially planar screen while preserving the convergence of the beams over its entire surface.

The object of the present invention is to minimize the deformation of NORTH / SOUTH geometry caused by a substantially flat screen while preserving the convergence of the electron beams.

The deflection device for cathode ray tube with three coplanar guns, according to the present invention, comprises a pair of horizontal deflection coils and a pair of vertical deflection coils, each horizontal deflection coil being characterized in that the angular distribution the density of ampere-turns in said coil changes sign at least one point in an area limited to the front part of this coil.

The invention will be better understood using the figures below, among which
FIG. 1 shows a section, along a plane perpendicular to the longitudinal axis Z of the tube situated in front of the deflector, on the screen side, of the pyramidal volume of deflection; There are represented the horizontal and vertical magnetic fields as well as the forces exerted on the electrons which will form the upper right corner of the image.

FIG. 2 is a perspective view of a saddle-shaped line coil of a known deflection device
FIG. 3 is a perspective view of a saddle-shaped line coil according to the present invention.

 FIG. 4 is a sectional view along a plane perpendicular to the main axis Z of the tube, of the front part of a saddle coil according to the present invention.

-Figure 5 illustrates the angular variation between 0 and 90 "of the functions cos e, cos 3e, cos 5e ..., of the function of distribution of the density of ampere-turns in a deflection coil
FIG. 6- represents the results of the amplitude measurements of magnetic fields along the Z axis created by a line coil according to the present invention.

 FIG. 7 shows the influence on harmonic 2 of the magnetic field of a coil structure according to the invention.

 FIG. 8 shows the influence on harmonic 4 of the magnetic field of a coil structure according to the present invention.

 FIGS. 9 and 10 illustrate variants of the present invention.

 It is customary to divide the deflection system into three successive action zones along the Z axis; the rear zone, closest to the electron gun, has a particular influence on coma or difference in size of the green image compared to the blue and red images; the middle zone of the deflector acts more particularly on astigmatism or the convergence of red and blue electron beams; Finally, the front area, located closest to the screen of the tube acts on the geometry of the image that will form on the screen.

FIG. 1 shows the action of the lines of force of the magnetic fields of horizontal deflection 1, along the direction of the X axis and vertival 2, along the disrection of the Y axis, on the geometry of the image. In the figure are represented in A the electron beam corresponding to the upper right corner of the image and in 3 and 4 the electron beams corresponding to the edges of the image. By decomposing the magnetic fields and the forces they create on the electron beams, we notice that these forces (FVy and FHx), resulting from the cushion forms of the line field and the barrel of the weft field, tend to draw on point A so as to correct the horizontal cushion deformation (NORTH / SOUTH) and to amplify the vertical cushion deformation.

For the line deflection field to have a cushion-shaped distribution, the distribution of the turns of the line coil must be such that the Fourier series decomposition of the angular distribution of the ampere-turns density in the coil makes appear a significant harmonic percentage 3 compared to the fundamental.

I1 is known that to increase the percentage of harmonic 3, the wire conductors of the coil 21, visible in Figure 2, extending in the direction of the main axis Z must be packed as close as possible to the plane XZ . As shown in FIG. 2 representing a line coil 21 in the form of a saddle seen in perspective and FIG. 4 representing a coil of this type seen in section in a plane perpendicular to the axis
Z, the lateral conductors 23 of the coil 21 meeting the desired criteria are contained in the smallest possible angular opening Ol. If it is possible to achieve the convergence of the beams by such a distribution, correcting the NORTH / SOUTH geometry for a tube having a screen of small curvature, or even completely flat is then impossible, physical limitations due to the bulk of the wires do not not allow reaching the desired t values to obtain a suitable harmonic level 3. In particular, it is impossible to obtain a harmonic coefficient 3 close to or greater than that of the fundamental. In addition, it is known that this coil structure introduces a large percentage of harmonics 5, responsible for the discrepancy of the electron beams in the corners of the screen.

French patent FR2411486 describes a coil, represented in FIG. 2, in which the direction of the current is reversed in a part 20 (in dotted lines in the figure) of the coil 21. This structure makes it possible to increase the proportion of harmonics 3 but also causes the super-convergence of the electron beams if this part is very large as is the case when it is a question of correcting the geometry of a screen with a large radius of curvature; in addition, the turns 20 decrease the L / R ratio between the value of the inductance of the coil 21 and its resistance, which has the consequence of increasing the power supplied necessary for scanning the screen.

The device of Figure 3 describes an embodiment of the present invention; the line deflection coil consists of a two-part winding
-a main deflection coil extending over the length of the deflector along the Z axis and whose lateral conductors are packed as close as possible to the XZ plane
an auxiliary deflection winding arranged in the front part of the main coil and supplied so as to generate a field of direction opposite to the direction of the field created by the main winding.

Figure 4 is a sectional view along a plane perpendicular to the main axis Z of the tube of the front part of a saddle coil according to the invention.

Given the symmetry along the Y axis, only the section of a half-coil is shown. This half-coil comprises a first part constituting a main coil 21, the conductors 23 of which are supplied so that the current passing through it flows in a certain direction 30 and a second part 22, constituting an auxiliary coil situated at the front of the diverter, supplied so that the current in the conductors 24 flows there in a direction 31, opposite to the previous one.

The conductors 24 are arranged in such a way that they occupy an angular opening (# 1 # 2) and are distributed around an average angle, on either side of which there is a substantially equal number of conductors 24.

The principle of the invention will be better understood by writing the equations which govern the magnetic deflection. Due to the symmetries of the deflector windings, the Fourier series decomposition of the ampere-turns density N (e) of a coil is written
N (e) = A1.COS (e) + A3 .COS (3e) + A5.COS (5e) + ... + AK.COS (B) + ...

The magnetic field created takes the expression: H = A1 / R + (A3 / R3>. (X2, y2) + (A5 / R5) - (X4 -6.X2.Y2 + Y4) + where R is the radius of the ferrite magnetic circuit which covers the deflection coils in order to concentrate the fields to improve the energy efficiency of the deflection device and A1 / R represents the fundamental field, (A3 / R3). (X2 -Y2) harmonic 2 of the field, (A5 / R5). (X4 -6.X2.Y2 + Y4) harmonic 4 of this field etc ...

Thus, a positive A3 term corresponds to a harmonic 2 of positive field and induces lines of field strength in a cushion.

In this context, Figure 5 represents as a function of e, the terms COS (e), COS (3rd), COS (5th) ... for e between 0 and 90 ".

For N (e) positive, as in the case of the main coil, the term A3 is positive if the conductors constituting the winding are arranged between e = 0 "and e = 30", values for which COS (3e) is positive. To have a very high harmonic rate 3 created by the main winding, the conductors constituting it will preferably be arranged between 0 and 20 values for which COS (3e) remains greater than 0.5 I1 is possible to increase the proportion of harmonic 3 by reversing the direction of the current in the auxiliary winding; N (e) becomes negative and A3 remains positive if
COS (3e) is negative; it is therefore possible to introduce positive harmonics in this way by winding conductors in the opposite direction in an angular position between 30 and 90 ". It is preferred to choose an average angular position s of the conductors 24, at least in the front part of the coil 22, between 55 "and 65" so that this coil has a maximum influence in this region on the harmonic 3 because in this zone,
COS (3e) is very close to -1.

The angular position of the conductors of the main coil, between 0 and 20, introduces a large percentage of harmonic 5 of the density of ampere-turns which can be compensated by the same auxiliary winding by placing the conductors 24 in a area where
N (e) .COS (5e) is negative (in order to avoid the harmonic 5 introduced by the main coil) which, for N (e) negative can be achieved by placing the majority of the conductors 24 in an angular position between 54 and 90 ".

In the same way it is possible to compensate for the influence of the higher harmonics introduced by the main winding by an adequate arrangement of the conductors 24.

Finally, if necessary, it is possible to adjust the percentage of the different harmonics with respect to the fundamental by varying, depending on the position along the Z axis, the average angular position g and / or the angular opening (e1 - e2) of the conductors 24.

In particular, to obtain a less significant action of the winding 22 on the harmonic rate 3 in the part furthest from the screen, this in order to avoid over-converging the electron beams, the average angular position g increases as and as you move away from the screen.

This coil structure also makes it possible to limit the reduction in the L / R ratio of the horizontal deflection coil to acceptable values because in this case the conductors 24 occupy a smaller area than the conductors 20 of the prior art .

In one embodiment of the invention, intended to equip a tube manufactured by the company ZENITH, with a flat screen approximately 40 cm diagonal, the auxiliary winding is arranged in the front third of the main winding.

The coil 21 extends in Z over a length of approximately 90mm and has 32 turns while the coil 22 extends along Z over a length of 20mm and has 14 turns. The two windings are arranged in series, so that the current in the auxiliary winding flows in the opposite direction to the current in the main winding. The arrangement in series of the two windings is not limiting, the winding 22 can be obviously supplied by a second external source. The conductors 24 are arranged around an angular position g between 58 "and 71", increasing at as one moves away from the part of the winding closest to the screen of the tube, the conductors 24 being wound between 54 and 80 ". The deflection device is divided into three zones, the front zone 47, closest to the screen of the tube, the central zone 46 and the rear zone 45, FIGS. 6, 7, 8 represent, along the axis Z, the modifications of the amplitude of the line field of the deflector 43 introduced by the auxiliary coil positioned at 44 in the front part 47 of the main winding, that is to say as close as possible to the screen of the tube. The amplitude of the harmonic 3 is roughly doubled, by 51 without the coil 22 to 41 after addition of this coil; thus the amplitude obtained 41 of harmonic 3 is found to be higher than that of fundamental 40 by about 12%. In addition, in the action zone 44 of the auxiliary winding, the amplitude of the harmonic 5 is reduced from 52 to 42, thereby improving the convergence of the beams in the corners of the screen.

In an advantageous embodiment, some of the conductors 23 of the main winding 21 located in the middle part 46 of the deflector are offset towards the inside of the coil 21 over a length 48. Figures 9.1 and 9.2 illustrate this embodiment by showing a line coil in which all of the conductors are offset towards the inside of the coil.

In a section along a plane perpendicular to Z passing through zone 48, this offset is represented by the gold angle. This offset makes it possible to locally decrease, in zone 46, the importance of harmonic 3 of the angular distribution of the density of ampere-turns in the winding, an excessive value of which could lead to a deconvergence of the electron beams, but which it is necessary to have in zone 47 to be able to obtain an effective correction of the cushion deformation.

Adapted to the ZENITH flat screen 40cm diagonal tube, the conductors of the coil 21 of the diverter fitted to this tube are offset by an angle equal to about 10 in the middle zone 46.

In another embodiment, represented in FIG. 10, the coil 22 creating a magnetic field coming to oppose that of the main coil 21, consists of conductors of the main coil, wound in such a way that they open a window 35 in the crown 36 of the main winding, window extending towards the inside of the coil 21; therefore the current flows in opposite directions 30 and 31 in the two winding parts 21 and 22.

Claims (4)

1-Deflection device for cathode ray tube with three coplanar guns, comprising a pair of horizontal deflection coils and a pair of vertical deflection coils, each horizontal deflection coil being characterized in that the angular distribution of the density d ampere-turns in said coil changes sign at at least one point in an area limited to the front part of this coil. 2-deflection device according to claim 1 characterized in that, in the front part of each of the coils of the pair of horizontal deflection coils, the amplitude of the harmonic of rank three of the Fourier series decomposition of the angular distribution of the ampere-turns density is substantially equal to or greater than that of the fundamental. 3-deflection device according to claims 1 or 2 characterized in that the pair of horizontal deflection coils consists of two coils each comprising two winding parts:  -a main deflection coil extending over the length of the deflection device  -an auxiliary deflection winding disposed in the front part of the main coil and supplied so as to generate a magnetic field opposite to the field of this main coil 4- Deflection device according to claim 3 characterized in that the conductors of the auxiliary winding are , at least in the front part of this winding, laterally arranged around an average angle chosen between 55 and 65. 5- deflection device according to claim 3 characterized in that the conductors of the auxiliary winding are laterally arranged around a mean angle whose value varies according to the position of the conductors along the main axis of the tube 6-deflection device according to claim 5 characterized in that the value of the mean angle around which the conductors of the auxiliary winding are arranged increases as one moves away from the front part of this winding 7-Deflection device according to any one of claims 3 to 6 characterized in that the majority of the conductors of the auxiliary winding are laterally arranged in an angular position between 54 and 90 "8-Deflection device according to one of claims 3 to 7 characterized in that the conductors of the main winding and the auxiliary winding are arranged in series 9-deflection device according to any one of claims 3 to 8 characterized in that the conductors of the auxiliary coil consist of a part of the conductors of the main coil 10-Deflection device according to any one of claims 3 to 9 characterized in that a part of the conductors of the winding main, located in the middle part of this winding, is offset towards the inside of the winding ll-Cathode ray tube characterized in that it is equipped with a deflection device according to any one of the preceding claims.