NO121561B - - Google Patents

Description

Horizontal deflection circuit for television receivers.

The present invention relates to a horizontal deflection circuit for television receivers with a high-voltage voltage supply,

in which receivers a controlled electronic switch and a saving diode are used.

Horizontal deflection circuits for high input voltages, on e.g. 220 - 250 Volt,, has so far only been realized with the help of tube-equipped circuits. A power pentode has then served as a controlled switch. In order to recover the energy, a series- or parallel-connected additional diode is used.

Semiconductor circuits have so far only been produced for relatively low input voltages, due to the fact that the collector-emitter voltage for transistors cannot be increased arbitrarily. In such circuit arrangements, relatively expensive power supply units must be used to generate a relatively low input voltage and a correspondingly high input current. For this reason, until now only tube-equipped circuits have been used for the horizontal deflection in television sets for stationary use.

Thyristors have recently been developed with an unusually high peak value of the blocking voltage between anode and cathode. Such thyristors can be operated with such a high input voltage that the costs of the power supply do not become greater than for tube-equipped equipment. These thyristors can be switched to their non-conducting state by a strong control current.

They are therefore usually referred to as breaking thyristors.

But an unusually high current is required to drive such a thyristor into the non-conducting state, this current being almost as high as the maximum anode current. However, this control current only flows after the zener voltage of the control characteristic of the thyristor has been overcome. Consequently, a relatively high instantaneous power is required to make the thyristor non-conductive. The drive stage must either be operated with a low supply voltage as before, but then you let go of the pre-

parts that thyristors with high control voltage provide, or the control current must be connected between the drive stage and the output transistor by means of transformers. But a pulse transformer must comply with extremely high requirements with regard to leakage inductance. In addition, two relatively expensive coils are required for the conventional thyristor-controlled circuit, in order to form a defined shape of the operating pulses in order to thereby reduce operating losses.

The purpose of the present invention is to produce a circuit which can be controlled by high voltages as well as by low voltages such as e.g. from simple transistor output circuits. One thereby achieves that a transistor can be used e.g. as an oscillator for influencing the circuit which can also be operated by means of a high input voltage. This is achieved according to the invention by producing a circuit in accordance with the requirements set out below. This results in an advantageous connection,

as the transistor is introduced into the cathode circuit of the thyristor and a practically constant positive voltage is fed to the control electrode of the thyristor which, together with the junction or zener voltage of the thyristor's input, is less than the permissible collector-emitter voltage for the transistor.

Another important advantage that one achieves with a circuit according to the invention is that one automatically gets protection against overload, such as e.g. may be due to high voltage overshoots. In a conventional thyristor circuit, where the cathode is grounded and the thyristor is switched to its non-conducting state by means of a negative current in the control electrode, it can happen that an extremely high thyristor anode current flows just before and during the application of the inverse control current, precisely because of high voltage discharges. Consequently, the inverse control current is insufficient to turn the thyristor into the non-conducting state. This means that the thyristor remains conductive, that the thyristor current assumes very high values and finally that the thyristor is destroyed. According to the invention, this is prevented by a series connection of transistor and thyristor, because the thyristor is not switched to its OFF state by means of a control current, but by means of an interruption in the cathode current of the thyristor to thereby make the transistor non-conductive.

In addition, the circuit according to the invention entails the advantage that even a so-called thyristor that cannot be switched off can be used. Circuits with such thyristors have until now only been able to be used in extremely complicated circuits where the thyristor is conductive during the return of the line, while it is non-conductive during the line forward scan.The use of transistors in the cathode circuit of the thyristor has the advantage that the transistor is protected from overloads due to the zener characteristic of the thyristor input.

The circuit will now be explained in detail by means of an example shown in the accompanying drawings. 2 denotes the transistor and 3 the series connected thyristor. 1 represents the input terminal of the transistor to which e.g. a rectangular control voltage from an oscillator not shown. A positive voltage of e.g. 5 volts is supplied to terminal 4, and this voltage is supplied to the control electrode of the thyristor 3 via the low-resistance protective series resistor 5. The saving diode 6 is connected in parallel with the series connection 2, 3. 7 denotes a capacitor which together with the line transformer 8 and the deflection pole 9 has a self-resonance which is such that a half-wave of this corresponds to the return period of the line. 10 is the terminal to which the high supply voltage is applied. 11 represents a high voltage rectifier from which the desired high voltage can be derived. Naturally, the diode 6 can also be connected in series, as this is conventional today for tube-equipped circuits, if it later becomes possible to produce thyristors with an even higher inverse voltage. When the rectangular voltage leading to terminal 1 changes in the positive direction, transistor 2 becomes conductive. Thereby, the voltage on the cathode of the thyristor 3 will drop to +0.4 V, so that the control electrode of the thyristor assumes a positive value corresponding to the cathode voltage. The thyristor 3 is consequently switched on. If the rectangular voltage applied to the terminal again changes in a negative direction, the transistor 2 will become non-conductive. Thereby the thyristor current is also blocked and consequently the thyristor is switched off. A positive feedback pulse is applied to the anode of the thyristor in the same way as in conventional circuits. The collector voltage of the transistor cannot in practice rise higher than the sum of the voltage applied to the control electrode of the thyristor and the zener voltage between the control electrode and the cathode of the thyristor. The operation of elements 6-11 does not differ from what takes place in a conventional deflection circuit.

Claims (1)

Horizontal deflection circuit for television receivers with high-voltage operation in which circuit an electronic switch consisting of a series-connected transistor and thyristor as well as an energy-saving diode is used, characterized in that the control signals for the switch are only fed to the base of the transistor, while the control electrode of the thyristor is supplied with a practically constant positive voltage which, together with the zener voltage of the thyristor input, is less than the permissible collector-emitter voltage of the transistor.