DE2941431A1 - CONVERGENCE CORRECTION DEVICE AND METHOD FOR A DEFLECTING UNIT OF A COLOR IMAGE TUBE - Google Patents

Description

The present invention relates to a convergence corrector according to the preamble of claim 1. Furthermore, the invention relates to a Convergence correction method according to the preamble of claim 16.

In color television picture tubes, pictures with parts of different colors are displayed generated by letting electrons fall on phosphors that emit in different colors. Usually phosphors are used, which emit red, green and blue light, respectively, and form a very large number of phosphor region triplets, each of which contain an area of one of the three color phosphors.

In the picture tube, the luminescent substances of the three different colors are each excited by an electron beam that only targets the luminescent substance should fall in a single color. The electron beams each have a cross-section which, in relation to a phosphor area-

030016/0902

29A I A '31

The group of three is relatively large, so that each ray has several Groups of three illuminated. The three electron beams are generated by three beam generating systems, which are in the neck of the picture tube opposite a screen containing the phosphors are arranged. The beam generation systems are arranged so that the electron beams leave the systems generating them on paths that are parallel to one another or converge slightly to the screen. So that different color tones can be produced in a certain color tone range, the phosphor arrangement in the respective image areas must be replaced by the three electron beams are excited with intensities that depend on the color to be reproduced. The three electron beams that the Leaving beam generating systems on separate paths, illuminate the screen in three different locations and generate separate ones Spots of different colors if the rays are not converged will. So that the three rays can illuminate one and the same surface and produce a desired shade, they are located on or near of the screens brought to convergence. In the middle of the screen, this can be done by means of a perineal magnet arrangement, which is located in the area of the neck of the picture tube and creates a static magnetic field that causes the three rays in the center of the screen coincide. This setting or adjustment is called "static Convergence ".

When the three electron beams cover the same area of the screen illuminate, some device must be provided to ensure that the red ray, the green ray and the blue ray, respectively only fall on the associated phosphor. This is achieved by a so-called hole or shadow mask. The shadow mask is an electric one Conductive screen structure or grid that has a large number of openings through which parts of the electron beams fall can. The openings each have a predetermined position with respect to the three groups of phosphor areas. Parts of the converging electrons fall through one or more breakthroughs and those that have failed Parts then begin to diverge and separate as they approach the screen. The reason for the direction of incidence of the electron beams the failed parts of the rays are separated on the screen and fall

030016/0902

294 U31

on the associated phosphors. The three electron beams approach so the different breakthroughs with something different Directions. The rays diverge somewhat after they have fallen through an opening and before they hit the different, associated phosphor areas impinge. The accuracy requirements regarding the arrangement of the phosphor area triplets with respect to the breakthroughs and the apparent origins of the electron beams are very high. The correct position of the apparent origin of the various electron beams is ensured by a "purity adjustment", which ensures that each beam only belongs to the associated one Illuminated fluorescent area of each group of three.

To create a two-dimensional image, the three must be static Converged electron beams generated light spot deflected both horizontally and vertically across the screen to form a luminous grid surface. This is caused by magnetic fields generated by one on the neck of the picture tube arranged deflection unit are generated. The deflection unit usually directs the electron beams with horizontal and vertical deflection systems that are essentially independent of one another are. The horizontal deflection of the electron beams takes place through two conductor arrangements of the deflection unit, which generate a magnetic field whose field lines run vertically. The amplitude of the magnetic field is changed at a relatively high frequency as a function of time. The electron beams are deflected vertically by two Conductor arrangements that generate a horizontal magnetic field that changes at a relatively low frequency.

The conductors of the deflection unit is a magnetically soft or permeable one Assigned magnetic core. The conductors generating the deflection fields form continuous turns or coils with return conductors, the in the case of a toroidal winding can loop around the core or can have the form of saddle windings if the coil does not cover the core surrounds.

030016/0902

The screen is relatively flat. The electron beams emitted by one Center of the distraction to the center of the screen go through a certain route, must travel a greater distance if they are distracted into a corner of the screen. For geometrical reasons it is to be expected that the electron beams converge at points on the surface of a sphere, the center of which coincides with the center of deflection; however, there the screen surface is not spherical, but relatively flat, this would already have the consequence that the points of impact of the three electron beams in the vicinity of the screen edge no longer coincide. In addition, cause unavoidable longitudinal components The deflection fields result in an even greater convergence of the electron beams, which further increases the surface on which the beams converge is distorted. These effects all together cause the light spots generated by the three electron beams to be outside the center of the Screen no longer coincide, even if each beam is only the one associated fluorescent color illuminated. This falling apart of the electron beams is known as a convergence error and creates color fringes in the reproduced image. Convergence errors are up to one Some size portable, however, a complete separation of the three spots is generally too obvious to be acceptable. The convergence errors can be expressed as the distance between red, green and blue lines of a cross-grating pattern that ideally cover each other metrologically detect, which are generated by a suitable test signal can.

In the past, kinescope tubes generally used a delta beam generating arrangement used, i.e. the beam generating systems were at the corners of an equilateral triangle. For color television tubes with such a delta gun assembly, the three electron beams were spaced on from the center of the screen Bodies brought to convergence by dynamic convergence devices, which contained additional convergence coils, which on the neck of the picture tube attached and by dynamic convergence circuits with deflection frequencies Streams were fed, as for example in US-PS 39 42 067 is described.

030016/0902

294 U31

In newer color television picture display devices, so-called In-line electron beam system arrangements in combination with self-converging Deflection units are used, such as is known from U.S. Patents 3,789,258 and 3,800,176. These self-converging Deflection units contain deflection coils that have negative horizontal isotropic astigmatism and positive vertical isotropic astigmatism which are chosen such that by a compromise between the convergence errors on the deflection axes and the convergence errors in the Corners is achieved that the rays at all points of the grid substantially converge. Coils and circuits for dynamic convergence can therefore be omitted. With the large deflection angles that occur with the commercial picture tubes with a short overall length are required, the deflection unit must correct for pincushion distortion as well as other artifacts and also provide satisfactory self-convergence cause. Because of the non-uniformity of the magnetic field resulting from the isotropic astiginatism required for self-convergence, the convergence depends on the position of the longitudinal axis of the deflection unit with respect to the longitudinal axis of the picture tube. This addiction and the Customary manufacturing tolerances make it necessary to adjust the deflection unit transversely to the longitudinal axis of the picture tube in order to achieve the best compromise to achieve convergence in terms of beam, this can, however, reduce raster distortion influence. When the position of the deflection unit has been adjusted so that the raster distortion is satisfactorily compensated for, on the other hand, a residual convergence error may remain. It is known that such residual convergence errors can be corrected by that you can make a strip of a magnetically permeable or ferromagnetic soft material at the deflection unit, the determination of the correct one Side of the picture tube to which this strip must be attached, the precise adjustment of the position of the strip and the fastening however, the strip of glue on the deflector is time consuming, since the person performing the adjustment is normally in front of the picture tube in order to carry out other alignment work and to observe the raster image while she has to go behind the picture tube to see the strips to attach.

030016/0902

294U31

The present invention is accordingly based on the object the adjustment work, in particular the correction of residual convergence errors to simplify and reduce the time required for this.

According to the invention, this object is characterized by what is defined in claim 1 Device and the method characterized in claim 16 solved.

A preferred embodiment of the convergence correction device according to the invention for a deflection yoke or a deflection unit that attaches the picture tube to a multicolor picture tube with an in-line electron gun arrangement surrounding and is substantially coaxial to her mountable, contains a first and a second magnetic field influencing device, the at or near the deflection unit on diametrically opposite one another Sides of the axis are arranged. A holding device holds the magnetic field influencing devices in a fixed mutual Distance and allows differential adjustment of these devices relative to the axis. In particular, the mounting device makes it possible to bring the magnetic field influencing device closer to the picture tube axis and at the same time the other magnetic field influencing device around the corresponding one Distance from the axis.

Show it:

Figure 1 is a perspective view of an arrangement of a picture tube and a deflection unit according to the prior art;

FIG. 2 shows a representation of possible residual errors that are corrected should be;

Figure 3 magnetic field distributions to which in the explanation of the Invention is referred to;

Figures 4 and 5 are rear and perspective views, respectively Arrangement of a picture tube and a deflection unit according to an embodiment of the invention;

03001 6/0902

29AU31

FIG. 6 is a schematic representation of another possible convergence error which is corrected by a device according to the invention can be;

Figure 7 different horizontal deflection fields on which in the explanation reference is made to the invention;

Figure 8 is a side view and a rear view of a

Embodiment of the invention in which two forms of convergence errors can be corrected independently of one another;

FIG. 9 is an exploded perspective view of a convergence correction device according to a further embodiment of FIG Invention mountable on a picture tube deflector assembly, and

10 shows individual parts or components of the device according to FIG. 9.

FIG. 1 shows a known picture tube deflection unit arrangement. The picture tube 10 shown schematically has a neck 12, in which electron guns are located, and an expanding one Part 14, which is traversed by the electron beams on their way to a phosphor screen, not shown. The deflection unit 20 contains a holder 22 which can be fastened to the picture tube 10, carries the various parts of the deflection unit and holds the deflection unit essentially coaxially to the picture tube. The bracket 22 includes a front one or front part 24 and a rear part 26, between which a Core 30 is located, which consists of two halves which are connected to one another by a fastening device 32. Every half of the core is associated with a toroidally wound vertical deflection winding 34. At the front Part 24 of the holder 22 of the deflection unit are arranged above and below magnets 36 for correcting a pillow-shaped raster distortion. The various connections of the windings 34 and the horizontal deflection windings (not shown) are arranged on a connection plate 38.

030016/0902

294U31

As described above, the deflection unit corresponds essentially the deflection unit, which is described in DE-OS 29 35 098.

As is known, it may be necessary to move the deflection unit 20 in the transverse direction in order to achieve an optimal raster correction. The deflection unit according to the above-mentioned laid-open specification can, for example, advantageously in the transverse direction during calibration in the factory can be adjusted in order to achieve the lowest possible cushion distortion. By a vertical translation of the deflection unit with respect to a small convergence error can occur in the picture tube, as is shown in FIG. Figure 2 shows a red and a blue vertical line, which go through the middle of the grid but do not otherwise coincide. With the oppositely directed translation of the deflection unit The blue line on the left and the red line on the right can of course be in the upper part of the grid. This convergence error is normally corrected, as is known, by placing a strip 40 of magnetically permeable material near the rear portion 26 of the holder 22 of the deflection unit is arranged either above or below the neck of the picture tube, as is shown, for example, in FIG. 1 is shown. After it has been determined on which side of the neck this strip must be, the strip is temporarily attached to a suitable place and the convergence is checked on the screen of the picture tube. If the arrangement is correct, the permeable strip 40 finally attached. If the position of the strip 40 is not yet correct, it is moved to a different location, which is again is determined by estimation, and the result is checked again at the front of the picture tube. This adjustment process is repeated until a satisfactory result is achieved. Hardly any is needed Note that this procedure is quite time consuming because the person making the correction moves several times between the front and the Back of the picture tube deflection unit to be adjusted and must move here.

FIG. 3a shows the ideal barrel-shaped field which is to be generated by the vertical deflection windings in the vicinity of the neck 12. The presence

030016/0902

29AU31

of the magnetically permeable strip 40 interferes with the horizontal magnetic Field lines and tends to increase the curvature of the field lines, such as the field lines 300, in the vicinity of the strip, as shown in FIG. 3b is. The straight field line 302, which previously went through the center of the deflection unit, is also bent and previously bent field lines, such as the field line 304, becomes straight and defines the new center of the field. The presence of a strip of magnetically permeable material tends to exist that is, to move the effective center of the field away from the stripe. One can thus find the effective center of the deflection field near the entry end of the deflection unit by using a strip of permeable Shift the material slightly in relation to the mechanical center.

Figure 3c shows the result of using two strips with equidistant from the center of the field of the deflection unit. The center of the field remains unchanged. When the two strips however, it can be used in an asymmetrical arrangement like it for the strips 40a and 40b in Fig. 3d is shown, the influence of one strip, that is, here of the strip 40a over that of the predominates other stripe, that is to say the stripe 40b and the center of the field changes.

FIGS. 4 and 5 show parts of a picture tube and a deflection unit

which contain an embodiment of the invention. the

Deflector includes a rear portion 426 (Fig. 4) that is channel-like Forms parts or grooves 450a and 450b. In that by the grooves 450a and 450b

Limited channel 450, a plate 452 is slidably arranged.

The plate 452 has an elongated central opening 454 that is wider

than the neck 12 of the picture tube, so that the plate 452 in the vertical direction can be moved without being obstructed by the neck 12.

In suitable wells of the plate are a first and a second Magnetic field influencing device attached to the present Embodiment the shape of plate-shaped pieces or strips

440a and 440b made of a magnetically permeable or soft material to have. The strips are on opposite sides of an axis 16 of the picture tube supported by the plate 652 and on the deflection unit arranged.

030016/0902

Both the plate 452 and the rear part 426 of the bracket of FIG Deflection units are made from a resilient thermoplastic material. The plate 452 is in the central area near the magnetically permeable strips slightly thicker than the edges engaging in the grooves. The course of the thickness of the plate 452 is with respect to FIG Dimensions of the grooves 450a and 450b dimensioned so that there is a frictional or press fit, the undesired displacement of the plate 452 prevented during and after adjustment. The adjustment of the plate 452 takes place by means of a molded onto the side of the plate 452 Rack 456 running in groove 450a. The bracket 426 of the deflection unit has a widening 460 with a hole 458 which is dimensioned so that that part of the groove 450a is exposed and space for a pinion 470 for driving the rack 456 is created. That shown in Fig. 5b Pinion 470 is of a diameter such that it fits into hole 458 and meshes with the teeth of rack 456. The pinion 470 is with a flexible drive shaft 472 connected.

The picture tube with attached deflection unit is used for adjustment inserted into a deflection unit adjustment device, not shown, by means of which the position of the deflection unit with respect to the picture tube can be adjusted from the screen side of the picture tube. The operator who is in front of the picture tube and is looking at its screen, adjusts the position of the deflection unit in such a way that the lowest possible raster distortion results. Any remaining convergence error is corrected by the operator by using the pinion 470 of the flexible drive shaft 472 and thereby rotates the plate 452 upwardly with respect to the deflection unit and the picture tube in the required manner or moved down.

The vertical displacement of the plate 452 causes a differential or opposing movement of the strips 440a and 440b towards and away from the axis 16, i.e. that the strip 440a is directed towards the neck 12 and the Axis 16 is closed when strip 440b moves away from the neck and axis. As explained with reference to Figure 3, this does this a shift in the center of the deflection field that can be used to correct the residual convergence error. The pinion 270 then becomes

030016/0902

294U31

removed from hole 458 and the picture tube deflector assembly is now ready for use. The plate 452 can, if desired be fixed by adhesive to prevent unintentional misalignment.

The same principle can also be used for the horizontal direction. FIG. 6 shows a convergence error in which the grid size plays a role. In Figure 6 is the horizontal dimension or width of the red grid is larger than that of the blue grid. Not shown The green or middle ray grid lies in the middle between the ones shown Raster. Distortion of this type can be corrected by an arrangement similar to that shown in Figures 4 and 5, but with the differential movement of the strips in a horizontal plane runs.

Fig. 7a shows an unaffected pillow-shaped magnetic field (or a field with a negative isotropic astigmatism).

The field line 602nst straight and, in the case of FIG. 3, represents the center of the The presence of a single strip of magnetic material displaced horizontally to the right with respect to the axis of the picture tube is, as Fig. 7b shows, has the consequence that the field line 602 is curved

and e \ e field line 600 just as that is, while the field lines can bleibt.Man curved 604 the strip so view as if it against the region of the greatest magnetic field strength isolates the axial region of the picture tube on the right side or shields which The field from the left gains more influence. By stretching the field line 600, the effective center of the magnetic field shifts to the right.

The use of two strips which are arranged symmetrically with respect to the axis results in a symmetrical field distribution similar to the unaffected field in FIG. 7a. An offset of the two magnetic material strips to the left, as shown in FIG. 7d, straightens the field line 600 and shifts the effective center of the magnetic field right, so that the same effects occur as when using the individual strip in FIG. 7b. The strips are adjusted so that that the red and the blue grid coincide.

030016/0902

The strips can be moved both horizontally and vertically by mounting the four strips on a swash plate, which can be moved vertically and horizontally. However, this can result in an undesirable mutual dependency of the adjustment processes. You can achieve an independent mobility in the two orthogonal directions by having two displaceable Provides carrier as shown in FIG. In Figs. 4 and 8 are Corresponding components are denoted by reference numerals which, with the exception of the hundreds digit corresponding to the number of the figure in question, are identified with one another to match. The device of Fig. 8 includes a horizontal sliding plate 852 carrying strips 840a and 840b which are positioned adjacent a central opening 854 which is larger than the neck of the Picture tube. The plate 852 is arranged in two slots or channels 850a and 850b which permit movement of the plate 852 in the horizontal direction allow. The plate 852 can have a not shown Drive mechanism be connected to the adjustment device so that it can be moved remotely to adjust the grid size.

The idea of the invention can of course also be put into practice in other ways than described. Instead of the rack and pinion gearing 456-470, for example, a force-fit gearing, such as a friction gear, can be used and the plate 452 can be supported and guided by slots and screws instead of through the grooves 450, and the permeable strips can also be arranged in a different longitudinal position are considered to be at the rear of the deflection unit. The drive pinion can be integrated into the deflection unit and form an integral part of this unit. The pinion can also be arranged at right angles to the position shown. The embodiments described above have the disadvantage that the sliding plates 452 and 482, on which the magnetic material strips are mounted, can extend beyond the edge of the main body of the deflection unit in their extreme positions. With certain deflection unit adjustment devices, the plate 452 and / or the plate 482 can interfere if these plates are not in their central position. It may therefore be desirable to provide the convergence correction device with a mechanism by which the magnetic strips arranged at the rear of the deflection unit can be moved in the vertical direction differential 1, which is not beyond the deflection unit or not further than

030016/0902

29AU31

-17-reaches beyond the extreme positions of the stripes.

In Fig. 9, a circular base plate 110 is shown, the one Central opening 114 has such dimensions that the neck of a picture tube, not shown, passes freely. The base plate 110 also includes locking or mounting arms 120 and 122, by which it is attached to the rear of a deflection unit, not shown can be, so at the beam entrance end. The base plate also has a vertically extending channel 112 and vertically extending slots 116 and 118 which run in the middle of the channel 112.

The base plate 110 is an injection molded or pressed part made of a relatively flexible plastic. It also has locking arms 124 and 126, which are integrally formed on the other parts of the base plate 110. The locking arm 124 contains a hinge-like acting bending point 130, which allows the locking arm 124 to be moved with respect to the main part of the base plate 110. In its one extreme position, a main part takes hold of the locking arm 124 into a cutout 136 and the outer parts of the locking arm 124 are then within the radius of the main part the base plate 110. In a corresponding manner, the latching arm contains a hinge-like acting bending point 128. The latching arms 124 and 126 contain ratchet teeth 134 and 132, respectively.

The convergence adjusting device according to this embodiment of FIG The invention also includes a strip carrier 150. The strip carrier 150 has a planar or flat body 151 which defines a central opening 152. The body 151 of the strip carrier 150 is dimensioned so that it fits into a channel 112 of the base plate and is displaceable in its longitudinal direction. The smaller dimension of the elongated Central opening 152 is sized so that the neck of the picture tube can freely pass through. On the body 151 of the strip carrier 150 strips 154 and 156 of magnetically permeable material are attached at the top and bottom, respectively. The body 151 jumps up and down, respectively a set of pins 158 and 160, respectively. The portion of the pin 158 extending rearwardly toward the base plate 110 is adapted for slidable engagement in the slot 116. In a corresponding way is the part of the pin protruding in the direction of the base plate 110

030016/0902

160 is provided for slidable engagement in the slot 118. The pins 158 and 160 slidable in the slots 116 and 118, together with those mating with the sides of the channel 112, prevent Sides of the body 151 each twist of the body 150 with respect to the base plate 110 and act as a guide that only allows vertical displacement of the strip carrier 150 allows.

The convergence correction device according to FIG. 9 also includes a rotatable drive plate 170. The drive plate 170 has a central opening 172 through which the neck of the picture tube can be inserted. Of the outer diameter of the drive plate 170 is slightly larger than the outer diameter of the base plate 110 and has approximately the diameter of the rear end of the deflector unit to which the base plate 110 is attached. At least part of the scope of the Drive plate 170 is provided with teeth 174 into which a drive pinion of a deflection unit adjustment device can engage.

In the side of the drive plate 170 facing the strip carrier 150 a second guide in the form of two channels 180 and 182 is provided. Channels 180 and 182 serve as control cams for pins 158 and 160. The spacing between cam-like channels 180 and 182 is equal to each other along each diameter of drive plate 170 Spacing of pins 158 and 160. Channels 180 and 182 extend in directions that have both a radial and a tangential component have with respect to the central axis of the base plate. In the assembled state of the device, the strip carrier 150 sits in the channel 112 and forms with the base plate a substantially flush surface against which the main part of the drive plate 170 can be applied. The drive plate 170, however, extends with its outer circumference beyond the outer circumference of the base plate 110. This protruding The area of the drive plate 170 is provided with internal teeth 184 (FIG. 11) along the circumference, with which the two plates follow the adjustment can be locked together. The drive plate 170 further has two arcuate slots 176 and 178, the Distance or radius from the center of the drive plate 170 is constant.

030016/0902

The slots 176 and 178 overlap part of the locking arms 124 and 126, so that the latching arms 124 and 126 are accessible and can be pushed outward to press the toothed parts 132 and 134 against the internal teeth 184 of the drive plate 170 and the entire Lock arrangement after adjustment.

The base plate 110 is attached to the rear of the deflector and kinescope assembly by placing its central opening 114 on the neck of the picture tube and fastened by means of the mounting arms 120, 122. The base plate is mounted with such an orientation that the channel 112 and the slots 116, 118 in the vertical direction get lost. The strip carrier 150 is then pushed with its central opening 152 onto the neck and the body 151 is pressed into the channel 112. Then the drive plate 170 with its central opening 172 pushed onto the neck of the picture tube and rotated so that the guide pins 158, 160 engage in the cam channels 180, 182. The locking arms 124, 126 are then pushed inward so that they pivot about the hinge-like bending points 132, 134 and their toothed Parts 132, 134 come to lie within the radius of the main part of the base plate 110. The drive plate 170 is then engaged with the pins 158, 160 and over the locking arms 124, 126 pressed.

The final assembly of the arrangement from the picture tube, the deflection unit and the convergence adjustment device can be made in a deflection unit adjustment device. A drive pinion engages during the adjustment of the adjusting device into the external toothing 174 of the drive plate 170 so that it can be rotated with respect to the base plate 110. When rotating, the cam follower pins 158 and 160 come to one another Position along channels 180 and 182. The rotational movement imparted to drive plate 170, however, cannot rotational movement of strip carrier 150 cause such through the guide pins 158 and 160 running in the slots 116 and 118 of the base plate 110 as well as through the sides of the channel 112 against which the sides of the body 151 abut is prevented.

030016/0902

After the convergence has been adjusted by rotating the drive plate 170, the operator performing the adjustment guides insert a screwdriver through the slot 176 and bring it into engagement between the end 124 of the locking arm and a cutout 136, around the end of the locking arm from an inner part 138 of the cutout 136 to push out, the end of the locking arm 124 then snapping into engagement with a part 140 of the cutout 136. Here are the Teeth 134 of the latching element 124 against the internal teeth 184 of the drive plate 170 pressed. In a corresponding manner, a screwdriver inserted through the slot 178 is used to lock the teeth 132 of the locking arm to press against the internal teeth 184 of the drive plate 170. As a result, the drive plate 170 is in the set orientation locked with respect to the base plate 110 and the strips on the strip carrier 150 are in a fixed position with respect to the base plate 110 and the rear part of the deflection unit.

It will be understood that both the slots 116, 116 and the channel 112 are sufficient in themselves to prevent a rotational movement of the strip carrier 150, so that each of these structures is also the first Guide can be used. When the slots 116, 118 are used in conjunction with the channel 112, they can form a loose fit, like that that they only serve to limit the vertical movement of the strip carrier 150 in the channel 112. The drive plate 170 can of course also be replaced by another device with respect to the base plate Lock 110 after the adjustment has been carried out, e.g. with screws or glue instead of the locking arms described.

It can also be seen that the distance between strips 154 and 156 is determined by the body 151 of the strip carrier 150 and is constant, so that the movement of one of the two strips has a corresponding Has the consequence of tracking movement of the other strip. One therefore needs in principle only one of the control cam-like channels 180 or 182 and a cam follower pin engaging in the relevant channel.

030016/0902

Maη can even omit the body 151 of the carrier 150 entirely, if the strips 154 and 156 are provided with suitable protruding pins. With such an arrangement there is then a constant distance between the strips ensured by the diametrical distance between the control cam channels 180 and 182. If such Arrangement without a guide channel is used and the strips each have only a single pin 158,160, as shown, the strips can rotate around the axis of the associated pin. Such a rotation can be prevented by having several Pins or an elongated follower used that engage in the guide channel.

The device described can also be used in one orientation use that by 90 ° compared to that shown in FIG Orientation is rotated so that the strips 154 and 156 are adjustable in the horizontal direction.

It is also possible to make the guides from ribs that protrude from the surface of the drive plate and / or the base plate. With such an arrangement, the ribs then engage in complementary slots or strip depressions in the magnetic material or in the strip carrier.

Finally, it should also be evident that the base plate can be formed as an integral part of the back of the deflection unit itself in order to save both material and assembly work.

030016/0902

Blank page

Claims (16)

DK. I) IETKII ν. HKZOLn I) IPl .. ING. I ¹ ETKH SCHÜTZ DIPL. IN (J. WOLFGANG IIEUSLEU MAHIA-TIIKHKSIA STHAHMK 99 PONTFAfII Η «IMKlH U-MO (K) MUKNCIlKN NO TKLKPON <Μβί «Τβ» Ο · TKLKX DtS2 «.18 TKLKUHAMH IiUMBKZ RCA 73.352 / 73521 / 73352Α RCA 73.352 / U.S.Ser.No. 951,001 / 12074/18906 Dr.v.B / Schä filed October 13,1978 / February 14,1979 / March 9,1979 RCA Corporation, New York, N.Y. V. St. A. Convergence correction device and method for a deflection unit of a color picture tube Claims Convergence correction device for a deflection unit, which can be mounted on a multicolor picture tube having an in-line beam generating system, surrounding it and coaxially to it two devices for influencing the magnetic field, which are arranged on the deflection unit, characterized in that the two devices (44Oa, 44Ob; 84Oa, 84Ob; 154, 156) for influencing the magnetic field are arranged on diametrically opposite sides of the axis and that a holding device (452; 852; 150) is provided which holds the two devices to influence the magnetic field at a fixed mutual distance and a differential adjustment of these two devices allowed with respect to the axis (16). 030016/0902 29A1431 -z- 2. Device according to claim 1, characterized in that that the two devices for influencing the magnetic field contain magnetically permeable strips. 3. Device according to claim 1 or 2, characterized in that that the two devices for influencing the magnetic field in the vicinity of the beam entry end of the deflection unit (20) are arranged. 4. Device according to claim 1 or 3, characterized in that that the holder contains a component (452, 852, 152), which the two magnetic field influencing devices (440a, 440b; 840a, 840b; 154, 156) at a fixed mutual distance and a simultaneous linear translational movement of the component and the two magnetic field influencing devices along a path which is perpendicular to said axis (16). 5. Device according to claim 4, characterized in that that the component (452, 852, 152) forms an opening (454, 854, 152) which is larger than the neck (12) of the picture tube (10). 6. Device according to claim 4, characterized in that that the deflection unit is assigned a guide channel (450; 850a, 850b; 112) which allows movement of the component with the exception of movement along the path perpendicular to the axis. 7. Device according to claim 5 or 6, characterized in that that the path is essentially perpendicular. 8. Device according to claim 5 or 6, characterized in that that the path is essentially horizontal. 9. Device according to claim 6, 7 or 8, characterized in that the component (452, 852, 150) has a 030016/0902 rack-like part (456), with which its position with respect to of the channel is adjustable. 10. Device according to claim 2, characterized in that with a body of the deflection unit (20) and the strip (154, 156) a first channel arrangement (112) coupled which prevents tangential movement of the strips around the axis (16), a radial movement, however, and that a rotatable drive device (170) is coupled to the body of the deflection unit, which one with the Strip (154, 156) coupled second channel arrangement (180, 182) contains, which contains radially and tangentially extending components and with the strip (154, 156) is coupled to a rotational force acting on the rotary drive in a radial acting on the strips To implement power. 11. Device according to claim 10, characterized in that the first channel arrangement contains two slots (116, 118) extending in the radial direction. 12. Device according to claim 11, characterized in that the two strips (154, 156) projections (158, 160) which engage in the two slots (116, 118). 13. The device according to claim 12, characterized in that the second channel arrangement has at least one third and a fourth slot (180 and 182, respectively) formed in the fixture and that the strips (154, 156) further Have protrusions (158, 160) coupled to the third and fourth slots. 14. Device according to one of the preceding claims, characterized characterized in that with the deflection unit (20) 'and the Holding device (150) a fixing device (124, 126) is coupled, which determines the relative position of the deflection unit with respect to the holding device allowed to be fixed after the convergence correction is performed. 030016/0902 29 4 I ^ ο 15. Device according to one of the preceding claims, characterized in that the mounting device contains an arrangement (456, 174) which can be coupled to a deflection unit. 16. A method for adjusting a deflection unit with respect to a picture tube, in which one after the other the deflection unit is mounted on the picture tube; the deflection unit is adjusted with respect to the picture tube in such a way that a minimal raster distortion results; characterized in that then two field influencing devices which operate on opposite sides Sides of a picture tube axis are arranged so differentieil be adjusted so that an optimal beam convergence results. 030016/0902