DE1762569C - Convergence deflection system for a color display tube - Google Patents

Description

* 2

The invention relates to a convergence problem in color picture tubes of the specified type Deflection system for a color display tube with kind of avoiding by deviations in convergence a combination of color luminous masses or rays that point to errors in the arrangement of the holding color screen and a single-electron beam generating device to the arrangement of the tronenkanone for generating and emitting 5 convergence baffles or for the convergence several Electron beams as well as with a deflection device are corrected Color screen associated beam selection device or compensated. Radiation is said to be with the color luminescent material combinations deviations that occur particularly at the corners of the speaking openings. The deflection system has a screen due to spherical aberration of the for focusing the rays on the color image- 10 scanning of the screen through the rays serve the screen Serving lens device, through which the deflection magnet yokes occur, dynamically opted out The center of all rays going through will be like.

and in the at least two of the rays at an angle to Accordingly, the starting point of the invention the optical axis of the lens device to converge a convergence deflection system for a color image verging Beam paths enter and out of the 15 display tube with a combination of these rays a> tf diverging ray paths from color screen containing color luminescent materials and to step. Between the lens device and that of a single electron gun for generating and Beam selection device is a convergence emission emitting multiple electron beams as well Arranged steering device for the beams, by with a beam associated with the color screen the on the diverging paths from the lens ao selection device with the color luminous mass com device exiting rays to converge binoculars corresponding openings. The distraction A system instructs the openings of the beam selection device to focus the beams be steered. the lens device serving the color screen,

In the case of color picture tubes with a single electron gun, all rays are blocked by their optical center Art will go through a ray generator or as and into at least two of the rays through a cathode device three electrons at an angle to the optical axis of the lens device rays enter at a lateral distance from each other on converging beam paths radiates and in a common, essentially and out of which these rays on diverging ray-horizontal plane passed so that the middle orbits emerge. Between the lens device Beam with the optical axis of the electron focus 30 and the beam selector is a converting lens coincides and the two outer genz deflectors are arranged for the rays, Rays in the optical center of the lens with through the on the diverging paths from the the central ray converge and the lens device exiting rays to converge, so that they emerge from the lens yawing on beam paths at the openings of the star menu selection device, which diverge from the optical axis. 35 can be distracted.

In the area of these diverging beam paths, this deflection system is designed as a result of this both sides of these pairs of convergence-deflection marked that at one point the optical Plates arranged, which have such a different axis on which the two rays at an angle to the electrical voltage is supplied so that they run the diver-optical axis, a device for producing Beams in a likewise essentially 40 generation of a magnetic flux with parallel to the optical Deflect the horizontal plane so that all rays are arranged on axis lines of force a point of the jet provided with openings. Further details of the invention emerge from wahJgitters or the perforated mask formed by this converge to the following one shown in the drawings, which is associated with the color screen presented embodiments as well as from the claims.

If when assembling a color picture tube 45 it shows

of this type the plane in which the three rays emerge. 1 a color picture tube with a single electron beam an angular deviation or cannon according to the invention in a schematic section, rotation or distortion with respect to the plane in one through the longitudinal axis of the color picture tube moves, in which the convergence baffle runs the diverging horizontal plane, deflect yawing rays, a cross-section with an ideal, non-thinning is produced between the 50, FIG. 2A Beams to the beam selection grid or the rotated course of the perforated mask from the beam generating device a vertical distance, whereby a direction generated rays,

incorrect color is formed because the rays Fig. 2B hit a corresponding cross-section in which the plane of the generated rays is twisted at least to a certain extent on color luminous masses, which do not entail the individual rays. 2A 'and 2B' address or not assign the location of the points of impact. Furthermore, the beam selection smoothing device or the shadow mask in which the earth's magnetic field or the beam path according to FIG. 2A and F i g. 2 B, as a result of mechanical errors in the alignment of FIG. 2B and 2B ', stirring beams onto the convergence baffles F i g. 4A Deviations at the corners of a dye * pneumatic tire instead of going through them freely. screen due to spherical aberration of the «Ab-Also, it is possible that the points of impact of the steering magnet yokes,

lamellar rays in the context of the usual Fig. 4B, the correct convergence of the rays Manufacturing tolerances eccentric to the openings β all points of the screen, of the beam mesh or the perforated mask, F Ig. 5A, SB and SC are graphic representations of A'Oftorch the color purity is adversely affected. Signals with sawtooth worlds to generate the Dv / invention is based on the object of this mapet flow according to FIG. 4A,

3 4

Fi g, 6 a schematic view of a coil for between the grid G ₁ and the electrode G ₃ Generation of a magnetic flux, which the exact electron lens field with the dashed line The rays pass between the auxiliary convergence lens L ' and through the electrodes G ₃ , G ₁ and G ₅ Brings about deflection plates, an electron _{lens field surrounding the electrode G 4} F i g. 7 a 5 composed of two coils with the main lens L also shown in dashed lines Device for generating the magnetic flux formed after. For the operation of the electron gun A

of the invention in side view, the respective cathodes Kh, Kq and Kb are

F i g. 8 shows an end view of FIG. 7, how the two grids G ₁ and G ₁ and the electrical F i g. 9 shows a section along line 9-9 in FIG. 8, the G ₃ , G ₄ and G ₅ preferably biases of F i g. 10, 11 and 12 one with the deflection magnet- io 100 V, 0 V, 300 V, 20 kV, 200 V and 20 V supplied,

In the electron gun A of FIG. 1 is a

generation of magnetic flux in front, side and electron beam convergence deflector Fan

Rear view. . . ordered, which are composed of the spaced-apart According to FIG. 1 is the invention in connection with superimposed and axially extending ab-

one a single electron gun for several 15 shield plates P and P ₁ as well as baffles Q and

Rays exhibiting color picture tube 10 is shown, Q ₁ , which is at a distance from the outer surfaces of the

the one with a dashed line glass envelope 11 with shielding plates P and P _x these opposite

Neck part 12 and cone part 13 verse '^ n, which are arranged. When the baffles Q and Q _x

extending from the neck part to a color screen S are also shown as rectilinear panels, so can

With the usual combinations of 20, this is also curved in a manner known per se Color luminous masses Sr, Sq and Sb as well as be designed with one.

Beam selection grids arranged at a distance in front of it. The shielding plates P and P ' and the deflection or a perforated mask Gp are provided. In the tube plates Q and Q ' are each equally charged and * neck 12 is an electron gun A with the catho- are arranged so that the central electron ends Kr, Kq and Kb are arranged, each of which through 35 beam B ₉ essentially is formed without deflection between a beam generating source whose beam passes through the shielding plates P and P ' , while generating surfaces, as shown, lie in a plane the electron beams Bb and Br, as shown, which are essentially perpendicular to the axis of the respective passages between the Plat electron gun A runs At _t the illustrated th P ', Q' and P, Q are deflected converging. Embodiment are the beam generating surfaces 30. For this purpose, the shielding plates P and P 'can each be arranged on a straight line so that a voltage Vp is supplied to each of them, which is equal to the voltage supplied to the beam Br, Bq and electrode G ₅ supplied by them, while the Bb in one the longitudinal axis of the electron gun A Deflection plates Q and Q 'are fed a substantially horizontal plane containing spinning Vq , which is about 200 to 300 V lower than the run with the central beam having the longitudinal axis 35 voltage Vp, so that the shielding plates P and P' of Electron gun collapses. At slightly the same voltage and having a deflection span distance from the cathodes Kr, Kq and Kb , a voltage difference or convergence deflection voltage Vc is arranged first grid Gi which is created in alignment with the between the plates P ', Q' and P, Q. will. Cathode ray generating surfaces with openings g _X R, This convergence deflection voltage Vc gives rise to g _x a and giB. At a distance from the first 40 necessary convergence deflection for the electron _{grids - G 1} , a common grid G _{1 is} arranged; Bb and Br radiate in.

that is in alignment with the openings of the first grating G _1.

is also provided with openings g _iR , g _tO and g _t a . areas of the cathodes Kr, Kq and Kb emitted

From the grid G ₁ , electron beams Br, B ₁ and B _B pass through the respective ones

tubular grids or electrodes G ₁ , G ₄ and G, 45 grid openings g, jj, g _t a and g _x a through and become

arranged, which are open at the front ends and with the »rcteni,» green «and» blue «intensity

sanunen with the cathodes Kr, Kq and Kb as well as the modulation signals between the cathodes

Grids G ₁ and G ₁ and the electrodes G ₁ , G ₄ and C, and the first grid G _{1 are} supplied in the

modulated in the position shown by holding intensity, not shown. The electron beams go

Devices are held from insulating material. 50 then through the common auxiliary lens L ' and

To operate the electron gun A of FIG. 1 intersect at the center of the main lens L to

will emerge diverging from this at the grids G ₁ and G _t as well as at the E! ek. Then goes

Trode G ₁ , G ₄ and G ₁ corresponding voltages differently with the electron beam B ₉ essentially without

placed. For example, the grid G _{1 will have} a chip deflection between the shielding plates P and P '

voltage from 0 to -4C0 V ₁ the grid G ₁ through a voltage 55, since these are applied to the same voltage,

from 0 to 500 V, the electrodes G _t and G _t a span · The penetration of the electron beam Bb between the

voltage of 13 to 20 kV and the electrode G ₄ a plate P ' and Q' and the electron beam Bt, between

Voltage from 0 to 4C0 V supplied, whereby all see the plates P and Q leads, however, as a result of the

these voltages to the cathode voltage as zero this applied convergence deflection voltage Vq

relate. Here, the voltage distribution can be between convergence deflections. The system according to FIG. 1

see the respective electrodes and cathodes as well as is designed so that the electron beams Bb, B ₉

their respective length and respective diameter im and Br then on a common pixel or

essentially equal to the voltage distribution of a in · light spot converge or become in this

directly heated single-beam electron gun »which cross the point between neighboring grids ·

from a single cathode and two superimposed 05 wires gp des determine the position of incidence of rays

the following, each have only a single opening

the bars. Deten mask Gp lies. From there the Sirah-

With the given voltage distribution, len and meet at the respective color mass point of the

FarbbildschlrmesSauf.Diesef istauieiner numerous and Bb in the opposite angle to the optical axis running Gruppsn or combinations extend vertically 'and have components across the * the "red,""greenmagnet" and "bluing" light MASSS * see lines of force directed lind . Composed of the "left-hand stripes Sr, So and Sb , where every rule of Fleming results" I mean that the rays Bn and Bb intersecting with the three groups of luminous material stripes or 'Combine 5 opposing angles' form a color picture element , perpendicular to the plane M in the image point or light spot of the ray convergence directions which the combination * corresponds to a color picture element formed in this way, the plane H and the plane H ' bring about and

The voltage Vp applied to the lens electrodes G 1 and O 1 and the plat · vertical deviations of the beam points, as applied in th P and P ′ , is also shown in FIG. 2 B 'are shown. The middle color screen S as anode sparging in the usual beam B ₀ is not influenced here because the force mode runs parallel to it via a graphite layer (not shown) to lines of the magnetic flux,
out, which is arranged on the inner surface of the tube cone 13 to generate the magnetic flux IS parallel to. The grid wires of the Gittere G _P may optical axis serving device 14 may as shown in, be a Nachfokusskrspannung Vu in i $ usual way constituted by a coil K, which are supplied to the order of 6 to 7 kV. around the in F i g. 3 tubes indicated by dash-dotted lines * The electron beams Bn, Ba and B * run like be * hals 12 and z. B. already mentioned in the circumferential direction, on the screen grid G *> is wound together and around the optical axis, so that the diverge from there in such a way that the electrical current flow through the coil K the desired matron beam Bb on the « blue «luminescent material stripes t * generated. The current for the coil K can be fed from Sb. The electron beam Ba to the green light an adjustable direct current source 17 with reversing ground strip S ₀ and the electron beam Bn on the real polarity, through the other "red" luminous ground strips S " atrftriffl. In the rest of the 4 force line density and direction of the same, the flee of the color screen will be brought about in the usual way parallel to the optical axis to form the color image on the color image * * s can to make the necessary rotation correction or screen z. B. scanned by the dashed lines shown horizontal compensation of the deviation of the beams Br and and vertical deflection device D to bring about the B _n.

horizontal and vertical deflection signals supplied when the beams B _R , Ba and B _B are scanned. Since, in the arrangement shown, the electrodes of the screen S are deflected by a deflection yoke D from the electron beam for focusing in each case through the a * convergence point in the center of the screen S from the center of the main lens L of the electron gun A , so that the length of the are the respective stretches through which the rays have to pass through the magnetic field of the deflection yoke D through the magnetic electron beams on the color screen 5, image points or light spots are essentially formed and spherical aberrations occur with the coma and free / or astigmatism is the main result that the rays are deflected differently, so that an improved color image resolution is achieved and ray deviations occur, in particular. those when these are on the corners of the color screen

The plane // (Fig. 2A) in which the rays Α _Λ , Ασ are directed. The beam deviation here and Bb should be emitted, with the horizontal because of the magnetic plane generated by the deflection yoke D , in which the beams B * and B _m pass through the con-fields for deflecting the beams in the vertical and vergence deflection device F Laterally deflected are both a vertical component and a horizontal direction. to coincide. If this is guaranteed, then there is a nente as well as a horizontal component. The lateral deflection of the beams Br and B ₈ horizontal component of the above-mentioned deviation can actually be compensated for by a coincidence of all beams can be compensated for by a device which does not belong to the object of the invention at a common point of the beam selection and which leads to the grating Gp , as shown in FIG. 2A 'is indicated the plates P and Q and the plates P' and ff dei If, however, as in FIG. 2B, plane H, convergence deflector F in addition to one. in which the rays are eaei, e.g. B. due to a static convergence deflection voltage still a «. Manufacturing error, another angular position to the dynamic convergence deflection voltage conveyed assumes plane H ' in which the beams Br and Bb V> which synchronize with the horizontal deflection signal is deflected by the convergence actuator Fab so that the deflections of the beams Br and Bb , the latter only leads to a vertical alignment, which is brought about by the convergence deflector F herder beams Br and Bb with the central beam B _a , for compensation or elimination on the grid Gp, but the beams are the horizontal component of the deviation developed in P i g. 2B 'are indicated, vertical distance 55 is changed speaking. How, however, F i g. 4 A shows have from each other. Such deviations from the horizontal direction will result in the vertical component of the convergence deviation resulting from the mentioned precise convergence both in the vertical and in the spherical aberration of the deflection yoke D in an uncorrected manner in the color image. hold when the rays hit spots on the screen

According to the invention, the vertical distance 60 will be directed which are spaced from the center of the screen of the rays at the ray extension grating Gp and in particular at the corners of the arrangement of a provision 14 according to FIG. 3 grain screens liegsn.

pensicrt and corrected, which are necessary for generating a According to the invention, such convergence

Magnetic flux 15 with the optical axis of the focus deviations of the beams Br, Bq and B _B , in particular lens L and thus with the central beam B _G par- 65 derc such deviations at the corners of the image. Lines of force on one of the hoof lens L ' umbrella, as shown in FIG. 4A are also shown and the convergence Abtenkvofricbbmg F is eliminated, so that cn all points at which the image point, ie at a point in which the rays Br screen is scanned, a full screen according to FIG. 4B

cared convergence is achieved. For this purpose, a beam Br and Bb is released between the plates P and Q

Magnetic field with running parallel to the optical axis' and passing between the plates P ' and Q' ,

the lines of force at one between the peripheral lens I _n and Be of the illustrated embodiment can be the Von

of the KonvefgtnZ'Abtenkvorrichtung F located point direction 22 to generate this magnetic flux ge *

üüf optischeil generated axis on which the rays Br 5 dimension F i g. 6 by one around the tube neck 12 *

and Bb run at an angle to one another, the intensity of the ring-shaped core 23 and the series-connected

and the direction of this magnetic field will be formed in the upper coils Ua and 246, which are in opposite ··

in accordance with the scanning of the screen 5 in the direction set in this way around the two core parts

changed so that at every moment those are arranged through this, those on both sides one through the optical

induced rotational displacement of beams Br and Bb io axis lying through vertical plane. the

just enough to get the beams to the correct converter- serially connected coils 24a and 246 are also

genz in the vertical direction. 1 to a direct current source 25 reverse

As shown, the last-mentioned magnet is connected with clear polarity, so that the flow

field with direct current running parallel to the optical axis through these coils an equal

Lines of force are preferably also generated by conducting a current with moderate magnetic flux with lines of force 26

generated in the coil 16. The current used for this (Fig. 6), the direction of which is determined by the polarity of the

is a dynamic convergence correction current, the current source 25 and its intensity by the size

is determined synchronously with the scanning of the screen of the stream. The magnetic flux 26 in the

changes and is supplied by a power source 18, in the plane perpendicular to the optical axis and in Rieh

according to FIG. SA a first sawtooth-shaped so lines that correspond to the plane in which the rays Br, Bo

Signal 19 in synchronism with the horizontal scanning and Bb are generated, run vertically, leads

signal and with the same oscillation period Ta as a simultaneous lateral displacement of the electron

this and a second sawtooth-shaped signal 20 radiate in one direction or the other,

according to FIG. 5 B in synchronism with the vertical Ab- whereby these are aligned exactly in such a way that

key signal and the same period of oscillation Tv as they are in alignment with the respective gaps between

this is generated. The signal 20 is used to see the plates P and P ' as well as Q and Q' of the con

Modulating the signal 19 by means of a push-pull vergence deflection device F ,

modulator used, whereby the output signal The magnetic flux 26 is preferably also

the power source 18 for feeding the coil 16 which is from close to the the optical center of the main

F i g. SC the shape of the waves 21 is evident. From the 30 vertical plane containing the focusing lens L F i g. SC shows that this is generated by the signal 21 so that all electron beams pass through the center

generated magnetic field itself during each horizontal of the magnetic field pass through it. In the case of the

Sampling period of oscillation of a maximum intensity. 7, 8 and 9 shown embodiment of the invention

sity in a direction towards maximum intensity are coil 16 and coils 24a and 2Ab in FIG

changes in the opposite direction, and that the 35 contain a coil group 27 which has a support member 28

Size of the maximum field intensities for each made of insulating material, e.g. B. a polyester resin, with a

vertical scanning oscillation and then reduced sleeve 29 such dimensions that they around the

is enlarged. In this way the rotary displacement tube neck 12 can be positioned around. the

tion of the rays Br and Bb, which through that of the sleeve 29 is at one end with longitudinal slots 30

Coil 16 supplied signal 21 is brought about, to 40 and a clamping ring 31 for fastening the support

a maximum at the corners of the screen and member 28 on the tube neck 12 is provided. Besides that

equal to zero in the middle of the screen. shows the sleeve 29 on the one facing the slots 30

So that the rays Br and Bb through the through the turned end a radial flange 32 and im Coil 16 generated magnetic flux similarly influences the axial distance from this one radial flange 33

the coil 16 is preferably close to the 45, which is directed away from the flange 32 with a,

through the optical center of the focusing lens / axial ring rim 34 is provided. As shown is

going plane arranged so that all rays the coil 16 between the flanges 32 and 33 on

wound through the middle of the sleeve 29 generated by the coil 16, and the core for the

Pass through the magnetic field. Coils 24a and 246 is shown in FIG. 8 through two In the case of small color picture tubes of the type shown, 50 halves 23a and 236 are formed which have at their ends

the distance between the shielding plates P and Q openings 35 for receiving support pins 36

and between the baffles P ' and Q' of the cones are axially from the flange 33 in the direction

vergence deflector F so small that the influence from the flange 32 protrude away. The core

of terrestrial magnetism on the electron beams or halves 23a and 236 wound around coils 24a and

a small mechanical error to the impact of the 55 246 are on the side facing away from the flange 32

one or the other of the beams Br and Bb on the flange 33 in the annulus between the

one of the corresponding convergence baffles sleeve 29 and the annular rim 34 housed and

can lead. In order to avoid such an impact, the in

can the picture tube 10 according to the invention with FIG. 8 and 9 indicated with dashed lines

a device 22 which is used to hold 60 adhesive members 37. Stand from the ring edge 34

one between the cathodes Kr, Kg and Kb and the terminals 38 and 39, which is connected to the coil 16 and the

Convergence deflector flying spots a coils 24a and 246 are connected to the respective Magnetic flux is applied to the power sources 17, 18 and 25 in a coil perpendicular to the optical axis.

create animal-running plane with lines of force that close.

essentially perpendicular to the plane in which the 65

Strä ^^ emitted, run. This also makes it possible that, although the electrical

«, ImiileWferidradig extent to the rays Br, Bg and Bb exactly at one point of the

1 So distracted that the beam selection grids Gp converge, this view

ίο

the points of impact in the horizontal direction are not in alignment with the openings of the selection grid or the perforated mask. Such deviations in the points of impact cannot . B, caused by errors in the manufacture of the color picture tube. The color picture tube according to the invention is therefore still provided with a device 40 shown in dashed lines in F ig, 1, which corresponds to device 22 and also 'if used to generate a magnetic flux in a plane perpendicular to the optical axis at a point between of the convergence deflection device Fund is the beam selection grid or the perforated mask Gp . The lines of force of this magnetic flux run perpendicular to the plane in which the beams Br and Bb are convergingly deflected, so that all beams Bn, Ba and Bb are laterally displaced by the amount required to align the point at which the Rays converge, with the point at which the rays converge with the centers of the beam selection grid or the perforated masks when scanning the screen, is necessary.

As shown in Figs. 10, 11 and 12, the device 40 for ensuring color purity may have two coils 41α and 416, which are wound around core halves 42a and 426 in opposite directions and connected in series with an adjustable direct current source of reversible polarity. The coils 41 and 416 are preferably arranged adjacent to the deflection yoke D angc which is used for the horizontal and vertical deflection for scanning the screen. This deflection yoke D has a frustoconical support sleeve 43 made of insulating material, which can be placed on the tube neck 12 at the transition to the tube cone 13 and is provided with radial flanges 44 and 45 which are arranged at both ends of the support sleeve. Annular coils 46a and 466 are arranged on an annular magnetic yoke 47. The yoke 47 is arranged around a sleeve 43 between flanges 44 and 45 in order to form the usual vertical deflection coil as shown in FIGS. According to FIG. 10, saddle coils 48a and 486 are arranged on the outer surface of the flange 45 and extend axially therefrom into the sleeve 43 and form the usual horizontal magnetic deflection coils placed around the tube neck. The core halves 42a and 426, which together form a ring, are fastened at their ends to screws 49 which are passed through the flange 45 so that the coils 41a and 416 are arranged radially outside the coil parts of the saddle coils 48a, 486 which are attached to the flange 45 rest. On the back of the flange 45, a terminal strip 50 with the connection terminals 51 is attached by means of the screws 49, which serve to connect the coils 41a and 416, the coils 46a and 466 and the saddle coils 48a and 486 with the associated circuits.

From the above description it follows that the deflection arrangement according to the invention for correcting and to compensate for verticals formed due to manufacturing defects or spherical aberration The spacing of the beams on the beam selection grid or the shadow mask is used in such a way that the One or more rays or bundles of rays impinging on the convergence deflection plates and furthermore any imprecise position of the ray convergence point to the center of the openings of the Beam selection grid or the shadow mask is avoided.

The devices 22 and 40, which are used to generate the magnetic flux in planes perpendicular to the optical axis of the focusing lens L , are designed as electromagnetic devices in the embodiment shown. The devices 22, 40 could also each consist of two ring magnets, not shown, with diametrically opposed poles, which are rotatable about the optical axis to change the field strength and direction of the lines of force of the magnetic flux.

Claims (12)

Patent claims: 1. Convergence deflection system for a color display tube with a color display containing a combination of color luminous masses and a single electron gun for generating and emitting several electron beams, as well as with a beam selection device associated with the color display with openings corresponding to the color luminous mass combinations, one for focusing the beams on the Lens device serving color screen arranged i Convergence deflection device for the electron beams is arranged, through which the rays emerging on the diverging paths from the lens device to converge Ren are deflected at the openings of the beam selection device, characterized in that at a point on the optical axis at which the two beams (Bb, Br) run at an angle to the optical axis, a device (14) for generating a magnetic flux (15) is arranged with lines of force running parallel to the optical axis. 2. deflection system according to claim 1, characterized in that the device (14) has a coil arrangement (16), which is arranged concentrically to the optical axis. 3. Deflection system according to claim 1 or 2, wherein the electron gun, the electron beams emits in a common emission plane containing the optical axis and in which the Convergence deflection allows the beam lying in the optical axis to pass undeflected and deflecting the other two beams in a plane containing the optical axis, thereby characterized in that the coil arrangement (14) is supplied with a static convergence correction current is connected to an adjustable direct current source (17). 4. deflection system according to claim 3, characterized in that that the coil arrangement (14) is also connected to a power source (18) for supply a dynamic convergence correction current is connected. 5. deflection system according to claim 4, characterized in that at a point between the beam generating devices (Kr, Kg, Kb) and the convergence deflection device (F) a device (22) for generating a second magnetic flux (26) is arranged in a plane perpendicular to the optical axis and not essentially perpendicular to the emission plane (H) directed lines of force. S. 6. deflection system according to claim 5, characterized in that that the device (22) is provided with coils (24 <J, 246) which are connected to an adjustable DC power source (2S) are connected (Fig. 6). 7. deflection system according to claim 6, characterized ge ίο ketdizeichnet that the coils (24a, 246) of the Generating the second magnetic flux (26) serving device (22) and the coil (16) for Generation of the first magnetic flux (IS) serving device (14) with only a small distance from one another are arranged (Fig. 1), 8. deflection system according to claim 7, characterized in that the coil (16) of the device (14) for generating the first magnetic flux (15) and the coils (24a, Ub) of the device (22) for generating the second magnetic flux (16 ) are each arranged on one side of the plane passing through the optical center point of the focusing lens (L), perpendicular to the optical figure eight and close to it. as 9. Deflection system according to one of the preceding claims, characterized in that a device (40) for generating a third magnetic flux in a plane perpendicular to the optical axis is arranged at a point between the convergence deflection device (F) and the beam selection device (Gp) . whose lines of force are essentially perpendicular to the plane in which the rays (Bm Bh) are deflected by the convergence deflector ^. * 10. deflection system according to claim 9, characterized in that the generation of the third Device (40) serving magnetic flux has a coil arrangement (41 u, 416) through which current flows, which is connected to an adjustable direct current source. 11. deflection system according to one of claims 4 to 9 and 10, characterized in that the for Generating the third magnetic flux serving device (40) arranged close to the deflection yoke (47) is. 12. Deflection system according to one of claims 4 to 11, characterized in that the da3 for feeding the dynamic convergence correction current serving current source (18) with means for Generation of a sawtooth-shaped first signal (19) is provided, the period of oscillation of which of the horizontal deflection signal and that with a second sawtooth-shaped Signal (20) is modulated, the period of oscillation of which corresponds to that of the vertical deflection signal (Fig. 5A, 5B, 5C). 1 sheet of drawings 1679