DE2261060A1 - DEFLECTION CIRCUIT FOR A TELEVISION RECEIVER - Google Patents

Description

Deflection circuit for a television receiver In line deflection circuits for a television receiver whose output stage is equipped with a transistor this transistor operated as a switch by alternating it through a pulse train is locked and controlled in the fully conductive, saturated state. The pulse train causes the transistor to be blocked at the beginning of the retrace time, so that the deflection current supplied by the transistor, which has then reached its maximum value, quickly drops back to zero. Because the transistor is saturated during the trace time State and thus there is an excess of charge carriers, must first this excess of charge carriers is reduced before the collector current drops can. However, this dismantling of load carriers takes a certain amount of time. If that If the collector current is switched off too slowly, this results in each case still existing collector current and the developing return voltage too high power dissipation for the transistor, which destroys it.

To achieve a quick shutdown, it is known to use the base current for the transistor to be deformed in such a way that already a few microseconds before the end of the trace time a breakdown of charge carriers takes place, whereby the collector current initially continues increases. The charge carriers are then at the desired moment of switch-off of the collector current already degraded so far that a rapid shutdown of the collector current through the base current takes place.

The known method of this type is described in DT-OS 1 762 326. There the controlling pulse sequence is fed to the transistor via a transformer, and for the aforementioned deformation of the basic currents, one between the secondary winding is used of the transformer and the base of the output stage transistor provided coil. These Coil is therefore necessary in order to achieve a quick shutdown of the transistor and destruction of the transistor due to excessive power dissipation if the speed is too slow Avoid shutdown.

The said coil is an additional one in the known circuit Component.

The invention is based on the object of this additional component to save.

This object is achieved by the invention described in claim 1 solved. Advantageous embodiments of the invention are set out in the subclaims specified.

Boi the known circuit according to DT-OS 1 762 326 was in contrast For the invention, the coupling of the transformer windings as tightly as possible, i.e. the leakage inductance of the transformer is designed to be as small as possible in order to keep the pulse train unchanged transfer. The pulse deformation took place. only through the additional, separated coil provided by the transformer.

In the solution according to the invention, however, a large leakage inductance, thus an intentionally loose coupling of the transformer windings with the transformer the desired pulse deformation is achieved, so that the additional coil is no longer necessary In addition, the advantage is achieved that the loose coupling of the transformer this results in a much simpler structural design for the transformer. While for the known fixed coupling in general a relatively large magnetic core with a closed magnetic path is necessary, e.g. one of two E-cores composite core, is sufficient for a transformer required in the invention o in a simple cylinder core without a closed magnetic path. The inventive loose coupling on the one hand saves the known coil and also leads to a simplified construction of the transformer.

The invention is explained on the basis of the drawing. In it show figure 1 a simplified circuit diagram of the invention, FIG. 2 curves to explain the Mode of operation and FIG. 3, 4, two structural versions of the invention, each in one Side view and a horizontal section.

Figure 1 shows a deflection circuit with a driver transistor 1, a transformer 2 with a primary winding 3 and a secondary winding 4, a Output stage transistor 5, a transformer 6 and line deflection sinks 7 in a simplified manner Shape.

FIG. 2 shows the associated voltage and current curves.

In order to quickly switch off the collector current 1 at the beginning of the c To reach the ramp-down time R, the base current Ig is already at the end of the ramp-down time H is deformed in such a way that it already corresponds to the curve segment during the time dt 8 falls off and thereby begins to reduce the excess charge carriers.

This deformation of the base current is in the known circuit by an additional coil between the upper end of the secondary winding 4 and the base of transistor 5 is reached.

In the invention, this coil is no longer required. The deformation of the base current is achieved according to the invention in that the coupling of the transformer 2 not as tight as possible as in known circuits, but rather loosely educated. This can be achieved by a certain distance between the primary winding 3 and secondary winding 4, e.g.

by an insulating layer or a thick insulation of the winding wire, or by intervening in the path of the magnetic flux through special training of the core.

Figure 3 shows a structural design of a transformer with a loose Coupling through special design of the secondary winding. On the middle leg 10 of a core lot 11 composed of two E-halves with an air gap in the middle leg 10, the primary winding 3 is fixed, located above the primary winding 3 the secondary winding, 4 ,.

whose inner diameter is larger than the outer diameter of the Primary winding 3 including isolation. The secondary winding 4 is seated with an air gap loosely on the primary winding 3, whereby a loose coupling is achieved. The winding 4 is designed as an independently stable coil, specifically as a so-called backing coil. The coil is first wound on a winding carrier. Then it becomes a stream sent through the coil, which heats the coil, the enamel surrounding the wire melts and thereby bakes the coil into a solid unit. the radial position of the secondary winding 4 is not critical; the winding 4 can also be arranged eccentrically on the winding 3. By an axial displacement of the Secondary winding 4 on winding 3 in direction 12 can change the coupling will. If the secondary winding 4 is in the correct position, it is covered with paint or glue set on winding 3.

In FIG. 4, the windings 3, 4 are on top of one another without any spacing Coil carrier 13 wound into which a straight cylindrical core 14 is inserted is. The loose coupling is achieved in that the core 14, in contrast to FIG 3 does not represent an almost closed magnotic path. The core 14 protrudes the end of the bobbin 13 by a piece b addition. The length of b lets affect the coupling between the windings 3.4. The arrangement according to figure 4 is an extremely small and easy to manufacture component. In particular As can be seen, the core 14 is particularly simple. Such a grain is usually not sufficient for a transformer because it does not allow sufficient fixed coupling. In the present skin, however, a loose coupling is advantageously used strived for.

Claims (12)

Claims Deflection circuit for a television receiver with a deflection current supplying transistor, at its base via a transformer a transistor periodically blocking pulse train is applied, with the base control current at the end of the outward run is so deformed that the opposite of a blocking of the transistor Charge tragor excess is reduced, characterized in that the deformation is achieved by a loosely formed coupling of the transformerwick lungs (3, 4). 2. Circuit according to claim 1, characterized in that the secondary winding (4) surrounds the primary winding (3) at a distance (a) (FIG. 3). 3. A circuit according to claim 2, dadurcnnze1kom that the secondary winding (4) is displaceable in the axial direction (12) relative to the primary winding (3) (FIG 3) .- 4. A circuit according to claim 2, characterized in that the secondary winding (4) is designed as an independently stable coil, the inner diameter of which is larger is than the outer diameter of the primary winding (3) (Figure 3). 5. A circuit according to claim 4, characterized in that the secondary winding (4) is loosely arranged on the primary winding (3) (Figure 3)). 6. A circuit according to claim 4, characterized in that the secondary winding (4) is designed as a baking reel. 7. A circuit according to claim 1, characterized in that the core (14) dos transmitter (2) is designed so that it does not have a closed magnetic Flow enables. 8. A circuit according to claim 7, characterized in that the primary winding (3) and the secondary winding (4) above or next to each other on a straight core (14) are arranged (Figure 4). 9. Circuit according to Claim 8, characterized in that the grain (14) protrudes beyond the ends of the winding (b in Figure 4). 10. Circuit according to Claim 1, characterized in that the loose Coupling is achieved through a suitably thick insulation of the winding wire. 11. A circuit according to claim 10, characterized thereby, then the insulation consists of a thermoplastic layer 12th Circuit according to Claim 11, characterized gekennzeivhnet that the insulation consists of a single or multi-layer silk covering consists.