DE976569C - Circuit arrangement for generating saegezahnfoermigen currents for the magnetic deflection of cathode rays in televisions - Google Patents

Description

The invention relates to circuit arrangements for generating sawtooth-shaped currents for the magnetic deflection of the cathode ray in televisions with a grid-controlled Tube and a transformer coupled with this diode and a capacitor in the diode circuit, the operating current being supplied to the tube through the diode. The invention enables a reduction in the power required. It is explained using the example of the transformer tilting device, in which particularly simple embodiments result.

Transformer devices are set up, for example, as shown in Fig. Ι. Anode and grid the tilt tube ι are fed back via the transformer 2. Due to the grid current that occurs the circuit generates its bias voltage in the 2? C element of the lattice circle. The deflection field will either formed directly by the transformer field or generated by deflection coils 3, which at a coil of the transformer can be connected, e.g. B. to the lattice coil, as in Fig. 1. The The grid-cathode section of the tilting tube acts like one made up of resistor 4 and capacitor 5

existing iiC-element linearizing biased diode on the field profile of the transformer and the deflection coils. By the grid tension or through the resistor 4, the natural frequency of the relaxation generator can also be influenced.

It is known to increase the linearizing effect by adding one to the deflection coils further through resistor 6 and capacitor 7 biased diode 8 with the lowest possible internal Resistor is connected in parallel (Fig. 2). Then the linearization plays through the grid-cathode segment the tilting tube only plays a subordinate role. The smoothing capacitor 5 (dashed lines drawn) can be omitted. A suitable choice of 4 and 6 can still be achieved be that the diode with the effect of the grid-cathode route of the tilt tube also their Load takes over, which is a considerable advantage for the tilting tube. Likewise then occurs in 4 only a low power and power consumption.

This circuit still has the disadvantage

indicate that the power consumption occurring in FIG. 6 for the flip-flop is lost. Furthermore, the voltage occurring at the i? C element (6/7) must be large compared to the voltage drop at the diode, so that the diode has a linearizing effect. The voltage drop occurring at the i? C element (6/7) or the power consumption occurring in 6 then appears inevitable.

To reduce the power consumed in the resistor of the diode circuit, it is already known to couple the diode circuit with the tube circuit by means of a transformer by adding the cathode of the diode instead of the anode of a tube controlled with a sawtooth voltage to a tap connected to a primary winding of a transformer arranged in the anode circuit of the tube with the secondary winding of which the deflection coils are connected. The current in the diode circuit is increased by the transformation to such an extent that it is equal to or greater than the anode current of the And the tube current can be fed through the diode by the positive pole of the tube Operating power source instead of the end of the primary winding of the transformer to the anode of the Diode is connected. Then only the difference between the tube and diode current, which corresponds to a correspondingly reduced power in the resistor. at In the known circuit, the voltage effective in the diode circuit becomes so as a result of the transformation greatly reduced that the voltage at the end of the primary winding facing away from the tube anode is essentially equal to the voltage of the operating power source, so that no current through the resistor flows and no power loss occurs in this. The operating voltage of the tube and thus the deflection power is not higher than with the previous circuits.

In a circuit arrangement for generating sawtooth-shaped currents for magnetic deflection of the cathode ray in televisions with a grid-controlled tube and one with this transformer coupled diode and a capacitor in the diode circuit, the anode current is fed to the tube via the diode, according to the invention the transformation ratio is transformer coupling between the transformer winding through which the anode current of the tube flows and the transformer winding through which the diode current flows such that in an equivalent circuit in which the The anode current of the tube 1 does not flow through the diode 8 and the diode current in one in the diode circuit lying resistor 6 bridged by a capacitor 7 generates the bias voltage of the diode 8, the diode and anode current are the same and the diode effect at the end of the current rise just suspends.

If you have chosen this dimensioning, you can use the anode current of the Feed tube 1 through diode 8 by removing the positive pole of the operating current source - as in Fig. 5 indicated - connected to the terminal of the capacitor 7 connected to the anode of the diode 8 and the resistor 6, which was previously parallel to the capacitor 7, is switched off (Fig. 5, Switch position 6).

With this dimensioning or mode of operation, not only - as with the known Circuit - either avoid the losses in the resistance of the diode circuit or those at the anode increase the effective voltage of the tube, but both advantages mentioned are achieved at the same time. When the diode current according to a feature of the invention, at the end of the current rise suspends, optimal conditions are achieved by all stored in the transformer winding Energy is harnessed.

In a special embodiment of the circuit arrangement identified above, in which the cathode of the diode to a tap on the winding located in the anode circuit of the tube Transformer is connected, according to a development of the invention, one end of the Deflection coils on a tap of the transformer winding located in the anode circuit of the tube connected. The elimination of a special output winding increases the efficiency the arrangement by reducing the losses in the transformer further increased and the Scatter between primary and secondary winding is reduced. ■

Fig. 3 shows a modification of the previous circuit according to Fig. 2, the circuit of a transformer tilting device. Here, too, the anode winding is located on the anode of the tilting tube 1 and on the grid the grid winding of the transformer 2. The deflection coils 3 are connected to a special output winding and parallel to them the diode 8 with the resistor 6 and the capacitor 7. The resistor 4 is partially adjustable, is relatively large and is only used for frequency control. To the A capacitor 9 smooths the anode current