DE930034C - Circuit arrangement for the magnetic deflection of the electron beam from television picture tubes - Google Patents

Description

There is already a circuit arrangement for -the magnetic deflection of the electron beam from the television picture tube !! became known to the one Circuit for obtaining the anode voltage of the picture tube from the line return at the deflection coils occurring voltage peaks is combined with a deflection coil system, which from a yoke body looping around the beam and looping around the cross section of this yoke body Windings.

In this scarf combination system, a particular advantage can be achieved in that a line deflection circuit with magnetic deflection of the electron beam in TV picture tube »used in which a voltage-resistant toroidal core coil is used as the deflection coil, which is located directly in the anode circuit a tube and which has a diode connected in parallel, and where the coil circuit is capacitive is closed via a network which contains a capacitor serving as a voltage source, on which an increasing trailing voltage causes is such that the mean diode current is practically equal to the mean anode current. This circuit is a voltage recovery without transformation.

The invention will now be described in more detail with reference to the figures. Figs. 1 'to 3 serve the Explanation of the prior art, while in FIG Circuit combination is shown.

Fig. Ι shows a known deflection circuit. The deflection coil AS lies in the anode circle of a tube,

whose grid is controlled by the line generator. A diode, which has a double function, is located in parallel across the deflection coil AS. Firstly, the diode ensures a constant voltage for the coil as long as it is conductive, and secondly it gives the deflection coil energy the opportunity to flow back to the supply source, which improves efficiency. However, the circuit shown in Fig. Ι has the disadvantage that a relatively high battery voltage is necessary to operate the circuit and that a current is drawn from the battery that has to cover the charge deficit, ie the difference between the average anode current and the average diode current. As is well known, the circuit shown in FIG. 1 generates a saw current curve as shown in solid lines in FIG. 3, in which the areas on both sides of the zero line are not equal, ie the mean diode current is smaller than the mean anode current, there is a charge deficit. In order to reduce the battery voltage and to avoid the Ladungsfehlibetrag, a circuit has become known, and in Fig. 2 dargesteillr in which a network N is provided, which separates · the deflection coil of the direct current circuit ^1. This network enforces the equality of area by generating a sawtooth rise curve with reverse curvature, as shown by the dashed curve in FIG. 3. This curve is enforced by a voltage on the coil that increases during the trace. The variable voltage is generated in that the trace capacitor C is part of an oscillating circuit and the anode current is controlled in a suitable manner. The trace voltage% increases during the trace with the difference in the sawtooth amplitude of u _z and Ui . From FIG. 3 it can be seen that in the case of FIG. 1 (solid curve) the diode current i _D smaller ate is the anode current i ^ and accordingly a charge deficit occurs, while in the case of FIG. 2 (dashed curve) the diode current is practically equal to the anode current. So the battery practically only needs to bring up the losses in the Schakungsteile. Without this network N , for example, a voltage of around 400 V was required to operate the circuit, while with the network shown, only a battery voltage of around 200 V is required, i.e. the receiver is also operated from a 220 V direct current network and could be designed as an all-current receiver or a direct-current receiver.

In order to obtain the anode voltage of the Braun tube from the voltage peaks during the line return, the circuit described requires a transformer T whose primary coil is also in the anode circuit of tube R and whose secondary side is used to draw the high voltage for the Braun tube. This transformer 'now requires a substantial portion (about a third) of the necessary battery feed current due to its inevitable losses. As a result of this transformer, a much higher battery capacity must be used. If, instead of a toroidal jacket coil that is not very resistant to tension, a tension-resistant toroidal core coil is used as a deflection coil, the pulse voltage can be increased significantly, ie practically doubled, and the high-voltage transformer T can be omitted entirely. In this way one achieves once that the necessary battery power can be kept low, since the losses of the high-voltage transformer are eliminated, and that the transformer itself is saved and the television receiver can still be designed as an AC or DC receiver. ·

Fig. 4 shows a Ausführungsibei game of the circuit combination according to the invention .. The same parts of the circuit are given the same reference numerals as in FIG. The difference compared to FIG. 2 is that a toroidal core coil is used for the deflection coil AS , that the transformer T is omitted and that a voltage doubler circuit SP is also provided for the high voltage.

The advantage of the invention over the circuit of FIG. 2 is that the battery power much less than that in the circuit (Fig. 2) needs to be and that in the circuit 4 shows a pulse peak of about 5 kV opposite only a maximum of 3 kV is permitted in circuit Fig. 2;

Claims (1)

Claim: Line deflection circuit with magnetic deflection of the electron beam in television picture tubes, characterized in that the deflection coil is a voltage-proof toroidal core coil which is located directly in the anode circuit of a tube and to which a diode is connected in parallel, and that the coil circuit is capacitively closed via a network which Contains voltage source serving capacitor at which a rising supply voltage is effected in such a way that the mean diode current is practically equal to the mean anode current will. 1 sheet of drawings © $ 09522 ά.