DE2629019A1 - Colour TV CRT deflection system - simplifies winding for pin cushion and barrel control with ferrite ring core - Google Patents

Abstract

The deflection system for colour picture tube of the shadow mask type uses toroidal coils wound by simple means and eliminates the necessity for ferrite correction elements. The ring core is then without grooves which must be aligned w.r.t. the electron gun, and the main toroidal coils are wound around the ring. The vertical deflection coils include more turns, and thus reduce the power required for the vertical deflection. The main winding H and the auxiliary coils H1/H2 are wrapped on the ring core by a toroidal winder, the auxiliary coils controlling the field in the front and rear of the core. A similar arrangement is used for the vertical deflection, and the auxiliary coils can be made by the printed circuit technique for a coil fitted on the inside of the ferrite ring core.

Description

Deflection arrangement for color picture tubes

PRIOR ART The invention relates to a deflection arrangement for Color picture tubes of the shadow mask type with a rear, almost cylindrical Part in which the electron guns to generate the electron beams side by side are arranged practically lying in one plane, and with a front, conical widening part, being approximately at the point of transition between these two Sharing a deflection system arranged coaxially with the tube axis is essentially located from a ring-shaped ferrite core, each with a pair of coils wound on it for the horizontal and vertical deflection exists. So it is, with In other words, toroidal coil deflection arrangements for so-called "inline" color picture tubes. Such toroidal coils are the subject of many German disclosure and interpretation documents, of which the DT-OS 22 12 557.1, 23 05 611.3, 23 19 056.9, 23 24 054.2, 23 24 102.3, 23 51 845.8 and 23 54 725.3 as well as the DT-AS 20 10 699, 21 27 657, 21 58 810, 21 59 385 and 23 09 581 should be mentioned. One now demands of the deflection arrangements that they are self-converging. In the case of a homogeneous deflection field, the converges 3 beams only in the middle of the screen, at every other point depending on the deflection more or less considerably in front of the screen, reflecting the flat, spherical surface deviating quality of the screen is due. One from the DT-OS 24 11 084.7 known The measure is to design the deflection arrangement in such a way that that for the horizontal deflection the field in the front area of the annular ferrite core of the toroidal coils in the shape of a pillow, as shown in Fig.ia, and in the rear area of the ferrite core, as shown in Fig.1c, runs barrel-shaped, with between These two areas the field, as shown in Fig.lb, also once runs homogeneously. The field for the vertical deflection is then in the front area of the ferrite core barrel-shaped, as shown in if, and pillow-shaped in the rear area of the ferrite core, as shown in id, again being between the two faces at one point a homogeneous field course, as shown in Fig.le, prevails. To those for such a Field training required to generate deflection fields, the angular position must be Change each wire in the direction of the tube axis, if this has a toroidal winding to be achieved on a toroidal core. However, such inclined windings are included Toroid winding machines are very difficult to manufacture in terms of winding technology. The difficult one The winding process extends the production time considerably.

Task, solution and advantages.

The present invention has for its object a deflection arrangement to be specified with toroidal coils, at least for the ring windings around the core the uniform, inexpensive type of winding and the necessary field change then by other, not designed as a ring winding and inexpensive to manufacture Winding parts is effected. The solution to this problem can be found in the claims.

The advantage of the deflection arrangement according to the invention is that without one complicated winding technology and without additional ferrite correction elements. At the toroid are included also not to provide any recesses, their The position of the winding must be taken into account and the centering of the entire system make more difficult. Since only the two main coil pairs are toroidal coils on the ferrite ring core are wound, the whole changing room can be used for this, so that especially the coils for the vertical deflection can receive more turns, resulting in a Reduction of the vertical deflection leads.

Description of the invention: The invention will now be based on the figures are described in detail. It shows: Fig.la ... f those for a self-convergence Required formation of the deflection fields, which was already described in the introduction.

2a and b show a division of the deflection coil pairs according to the invention.

3a-d show cross sections for a deflection arrangement according to the invention suitable annular ferrite cores.

Fig. 4 shows an example of a printed circuit on a foil applied auxiliary coil.

The required course of the deflection fields for a self-converging Deflection arrangement for an in-line color picture tube as shown in Fig.la ... f has already been described in the introduction. The DT-AS 1 107 835, and the DT-OS 2 341 646, as well as the article: The 20-AX-System "by W.Otten and J.Wölber in Funkschau 1974 issue 9 pages 299 ... 302 and issue 10 pages 374 ... 376 describe realizations such Deflection fields for saddle coil systems, but not for Toroidal deflection systems can be used and are also too expensive. How nice mentioned it is therefore the object of the present invention while maintaining the normal Toroid coil winding of a ring-shaped ferrite core ensures the required field distribution other, additional winding parts that are not applied with a ring winding machine, the production of which is simple and inexpensive and they are also now ScliVicrigJiten @@@ can be adorned. The auxiliary windings are desirable here Keep it as simple as possible and avoid additional correction elements.

The deflection coil arrangements for the horizontal deflection are now shown in FIG and in Fig. 2b that for the vertical deflection is shown as a current flow. The deflection coils are in main coils H and V and two auxiliary coils H1 and H2 and V1 and V2 been split, with the main coils of each deflection direction H and V, the Form the main part of the turns, still as a toroidal winding with a ring winding machine are applied to the toroidal core0 The two auxiliary coils, of which H1 and V1 are the Field course in the front area of the ferrite core and 112 or V2 the field course in the rear area of the ferrite core are affected than those applied to a film formed printed circuit, which rests against the inside of the ferrite ring.

For this purpose, the cross-section of the ferrite ring is expediently formed, as shown in Fig.3, so that its inner surface in one or two parts can be handled in one plane. The simplest form is that in Fig.

3a shown hollow truncated cone, its inner surface as a flat development results in a circular ring segment on which the two pairs of auxiliary coils are then arranged are that the influencing the field course in the front area of the Ferrite rings along the boundary circle with the large radius and that to influence the course of the field in the rear area of the ferrite ring along the boundary circle with the small one Radius runs. FIG. 3b now shows a ferrite ring shape made up of two hollow truncated cones composed.

Your development results in two annulus segments, with the smaller one the auxiliary coil pair for influencing the field profile in the rear area of the Ferrite ring and, on the larger one, the one for influencing the field profile in the front one Area of the ferrite ring is located. In Figure 4 is a segment of a circle with the on printed circuit board attached to it. In the ferrite ring shape shown in Fig.3c is modified according to Fig. 3b in that the smaller hollow truncated cone here is designed as a hollow cylinder, the development of which is then a rectangle.

If the ferrite ring shape that is common today and shown in FIG. 3d continues should be used, must be on a plastically deformable circular ring or Annular segment the printed circuits according to the methods of tin printing technology applied so pre-distorted that the windings after the thermoplastic Deformation then have the correct course desired.

Since two auxiliary coils are required for both deflection directions, On the inside of the ferrite ring, either 2 foils with a printed circuit, one for the horizontal and one for the vertical deflection are placed on top of each other, or there can be one coil on the front and one on the back the slide.

Since with the ring winding machine only the main coil pairs for the Horizontal and vertical deflection must be applied, can be better Utilization of the winding room set the number of turns for these coils, in particular for the vertical main coil pair are increased, resulting in a reduction the distraction leads.

The deflection arrangement described for color picture tubes achieves that this is implemented inexpensively with a simple, uncomplicated structure as a toroidal coil without making concessions with regard to convergence and image geometry need to be done.

3 sheets of drawings 7 claims Lee rse ite

Claims (7)

Claims: Deflection arrangement for color picture tubes of the shadow mask type with a rear, almost cylindrical part in which the electron guns for generating the electron beams lying next to each other practically in one plane are arranged, and a front5 conically widening part, with about at the point of transition between these two parts a coaxial to the tube axis arranged deflection system is provided, which consists essentially of an annular Ferrite core with a pair of coils wound on it for the horizontal and for the vertical deflection consists, characterized in that each of the two coils pairs is split into a main coil pair and two auxiliary coils so that the two pairs of main coils (H and V) as toroidal coils on the ring-shaped ferrite core are wound and the auxiliary coils (fix, H2 and V1, V2) are attached to foils, which rest on the inner surface of the ferrite core so that the individual coil sections (H, H1, 2 or V, V1, V2) of each pair of coils are connected in series and the two auxiliary coils (H1, H2 or V1, V2) are spatially arranged so that through the one the field course in the front area and through the other the field course is influenced in the rear region of the annular ferrite core so that results in the desired pillow-shaped and barrel-shaped design of the deflection field. 2. deflection arrangement according to claim 15, characterized in that the Inner surface of the annular ferrite core has the shape of a truncated cone jacket, that the two Elilfsspulen for one deflection direction as a printed circuit applied to a sheet of the same area as the development of the truncated cone jacket are that it is used to influence the field profile in the front area of the ring-shaped Auxiliary coil serving the ferrite core along the larger circumference and the course to influence the field in the rear area of the ring-shaped ferrite core serving auxiliary coil arranged along the smaller circumference of the truncated cone jacket are. 3. deflection arrangement according to claim 1, characterized in that the The inner surface of the ferrite core has the shape of the shells of two abutting truncated cones has different opening angle that each of the two auxiliary coils for a deflection direction as a printed circuit on each one of the development each one Truncated cone jacket is applied film of the same area that it is used to influence serving for the course of the field lines in the front area of the annular ferrite core Auxiliary coil on the one with the jacket development of the truncated cone with the larger opening angle the same surface film and the one to influence the course of the field lines in the rear Auxiliary coil serving the area of the ring-shaped ferrite core on the unwinding of the jacket of the truncated cone with the smaller opening angle arranged foil of the same area is. 4. deflection arrangement according to claim 3, characterized in that the Truncated cone with the small opening angle has the shape of a cylinder. 5. deflection arrangement according to claim 1, characterized in that the ring-shaped ferrite core has the shape of a truncated bell that for the manufacture of a Auxiliary bobbin with the non-developable shape of the inner surface of the bell stump the auxiliary coils for a deflection direction with a corresponding predistortion a foil with the same surface area as the development of a truncated cone jacket as a printed sheet Circuit are applied, with the to influence the field course in the front Auxiliary coil serving the area of the annular ferrite core along the larger circumference and those to influence the course of the field in the rear area the annular ferrite core serving auxiliary coil along the smaller circumference of the truncated cone jacket is arranged, and that by subsequent thermal deformation the truncated cone jacket in the shape of the non-developable inner surface of the truncated bell is convicted. 6. deflection arrangement according to one of claims 2 or 3 or 5, characterized characterized in that the auxiliary coils for each deflection direction on separate foils are upset. 7. deflection arrangement according to one of claims 2 or 3 or 4 or 5, characterized in that the auxiliary coils for one deflection direction on the The front side and that for the other direction of deflection are applied to the rear side of the film are.