DE2710665C2 - Self-regulating horizontal deflection circuit for cathode ray tubes - Google Patents

Description

Ul from the deflection circuit becomes too large and the Zener voltage of the Zener diode 20 exceeds. The previously known circuit arrangement, however, still has the disadvantage that, in the case of short-term Neti interruptions, as they occur, for. B. can occur with loose contacts in the mains socket, is not switched off quickly enough. By inserting a time constant with the help of the resistor 21 and the capacitor 22, which connect the collector of the transistor 12 to the base of the Transisto.'SU, it is achieved that even with brief interruptions in the voltage U1, the flip-over process is triggered immediately, since the negative voltage jump via the low-resistance path via the resistors 23, 21 and the capacitor 22 to the base of the transistor 11 which the flip-flop 10 returns to its starting position so that the line end 6 is activated again and ready for operation. After each switch-off, even if only briefly, the flip-flop 10 is held in its unstable state for about 5 seconds. The addition of the time constant element has a further advantage. During the switch-on process, the capacitor becomes

ίο 22 via the base-emitter path of the transistor 11 charged. During this charging time, the protective circuit 10 is deliberately made insensitive, otherwise it would react like an overload due to the increased charging current requirement and the device immediately again switch off. After the compulsory pause has expired, the protective circuit is automatically sensitive again.

H'-jrzu 1 sheet of drawings

Claims (1)

Claim: Self-regulating horizontal deflection circuit for cathode ray tubes, in particular for picture tubes in television receivers, to produce a sawtooth shape flowing through a deflection coil Deflection current and for generating several stabilized operating voltages, the deflection current during a first part of the trace time through a first diode and during a second part the trace time with opposite polarity through one in a parallel branch to the diode lying, pulse-controlled switch, e.g. B. a transistor, which flows during the second part of the trace and current-permeable during of the kickback is blocked, with feed energy from a supply voltage source between this source and the switch connected primary winding of a transformer supplied and is transmitted to the parallel resonance circuit in the flyback time, and at the end of the Trace time when the switch is made non-conductive, the magnetic stored in the transformer Energy from a secondary winding via a further diode that conducts during the flyback time to the Parallel resonance circuit is transmitted, and that the switch, which is connected to the primary winding of the Transformer is connected in series by a connected to the connection point of this series circuit, in the second part of the trace time, the conductive third diode is connected in parallel with the first diode, and the switch for changing the amplitude of the deflection voltage also during different parts of the first part of the trace is conductive controlled in such a way that the amplitude with the help of a control circuit through Change of the control pulse duration depending on fluctuations in the deflection voltage is stabilized, the control circuit has a protection circuit against interference that the Control pulses for the line output stage short-circuits in the event of a fault, characterized in that that the collector of the control short-circuiting transistor (12) of the flip-flop (10) via a Time constant element (21, 22) with the base of the transistor (11) receiving the interference information Tilting stage (10) is connected. The invention relates to a self-regulating horizontal deflection circuit for cathode ray tubes, especially for picture tubes in television receivers, for generating a flowing through a deflection coil sawtooth deflection current. Such a horizontal deflection circuit, which the amplitude of the Stabilizing deflection voltage., Is known (DT-PS 30 902) and in the Valvo development notices No. 61 of April 1975 described in detail. This horizontal deflection circuit also generates variously high stabilized operating voltages for the television receiver by during the first part of the Line follow-up the transistor in the output stage of the line deflection circuit takes over the power supply function by this is controlled by a control circuit with pulses of different lengths in such a way that the Abienkstrom remains constant. As a result of disturbances that can overload the line output stage, is in the known circuit in the Control circuit built-in a multivibrator that responds in the event of a malfunction and the control pulses for the line output stage shorts. Disturbances can occur e.g. B. in the form of Overload due to excessive current consumption from the regulated power supply unit or in the form of overvoltages or express it by brief power interruptions. In the latter case, it is particularly critical if the television receiver immediately afterwards after a short interruption of the operating voltage is switched on because of the loss of charge caused by the interruption of the supply voltage can be applied suddenly by the line output stage is must. The invention is therefore based on the object of protecting the line output stage in this case as well. the The object is achieved in a circuit arrangement of the type described in that the collector the control short-circuiting transistor of the flip-flop via a time constant element with the base of the transistor receiving the interfering information is connected to the flip-flop. This measure ensures that in the event of a power failure, the Output stage takes place, with a longer forced pause being inserted until the next possible switch-on, in which the initial conditions for the deflection and power supply circuit can be set. Achieved at the same time this reduces the sensitivity of the protective circuit during the switch-on phase. An exemplary embodiment of the invention is explained in more detail below with reference to the drawing. In the block labeled 1, line-frequency square-wave pulses are generated which the Control circuit 2 can be supplied. Depending on the emitter-collector current of transistor 3 a control voltage appears at the emitter of transistor 4, so that depending on this control voltage the square-wave voltage generated at the collector of transistor 5 with a different duty cycle can be removed, which is fed to the line output stage 6. The control circuit 2 receives its Information depending on a deviation z. B. the deflection voltage UX via the input 7 to the control electrode of the transistor 3. Deviations in the mains voltage LQ from the power supply unit 9 are also corrected via the input 8. In addition, the known circuit arrangement has a protective circuit in the form of the monostable multivibrator 10 with a transistor 11 and a transistor 12, the collector-emitter path of which short-circuits the emitter of the control transistor 4 in the event of a fault, whereby the control of the line output stage 6 is interrupted. In the normal operating state of the television receiving circuit, the transistor 11 is conductive and the transistor 12 is blocked. As a criterion for the overload, an alternating voltage proportional to the charging current is taken from the series circuit consisting of the resistor 13 and the capacitor 14 in the line output stage 6 via the resistor 15 and the capacitor 16. The positive components are clamped to ground potential by the diode 17. The alternating voltage, which is unipolar in this way, is reduced with the help of the filter, ^{fl <} i formed from resistor 18 and capacitor 19, screened. From a level of around -100 mV, the tipping process of level 10 is triggered. Likewise, the exclusion when the stabilized tension