DE2238982A1 - CIRCUIT ARRANGEMENT FOR THE DEFLECTION OF AN ELECTRON BEAM IN A CATHODE BEAM TUBE, IN PARTICULAR FOR THE VERTICAL DEFLECTION IN A TELEVISION RECEIVER - Google Patents

Description

Circuit arrangement for. the deflection of an electron beam in a cathode ray tube, especially for vertical deflection in a television receiver The invention relates to a circuit arrangement for deflecting an electron beam in a cathode ray tube with a deflection coil located in the output circuit of the output stage, at which a high return pulse voltage during the return time of the electron beam occurs, the operating voltage for the output stage during the ramp-down time has a higher value than during the trace time, especially for the vertical distraction in a television receiver.

In the case of vertical deflection, the deflection coil can understood as an approximately purely ohmic resistance.

because of the voltage drop over the inductive part is low compared to the voltage drop across the resistive deflection coil. While the flyback time, however, is caused by the inductive component of the deflection coil due to the fast Change in the deflection current creates a high voltage pulse across the deflection coil, which with the usual ramp-down time of 1 ms is 19 times as large as the voltage across the inductive part during the outward run. A more precise representation of the mode of operation and the voltage ratios of such a deflection circuit throughout The deflection period is given in the German Auslegeschrift 1,236,558.

So that the desired sawtooth-shaped deflection current in the deflection coil can form, the operating voltage of the final stage must be both sawtooth Voltage during the trace time as well as the pulsed voltage during the Apply return time. Because the return momentum in relation to that during sawtooth-shaped voltage -as indicated above-very much is large, only a part remains for the sawtooth-shaped part during the outward run of the operating voltage, so that the achievable amplitude for the sawtooth-shaped Voltage and thus for the deflection current is reduced.

From the above-mentioned German Aulegeschrift 1 236 558 it is known the output stage of the deflection circuit during the flyback time from the actual operating voltage switch off and switch on to a second operating voltage that is greater than the first.

This known short-term increase in operating voltage during the flyback time, it is possible that for the formation of the flyback pulse greater operating voltage is available and that thus during the delay time almost the entire actual operating voltage for the formation of the sawtooth-shaped Voltage can be exploited. The known circuit, however, is required for connection the power supply connection of the output stage to the two different operating voltages an electronic switch, which means an additional effort.

The invention is based on the object of creating a circuit in which the increase in the operating voltage during the return with a possible little additional effort is made.

The invention relates to the circuit mentioned at the beginning.

The circuit according to the invention is characterized in that as Operating voltage the output voltage of an electronically regulated voltage source serves, which is provided with a control input that as a control voltage for the The voltage source is a voltage derived from the return pulse voltage, and that the control input of the voltage source is connected to its control circuit is.

The use of the circuit according to the invention results in the Advantage that essentially only existing circuit parts additionally for the increase in the operating voltage can be used. The direct intervention in the The control loop of the stabilized voltage source that is already present does not mean any additional effort. In the worst case, there are only a few components for Derivation of the control voltage required for the voltage source. The circuit but can easily be set up in such a way that even this effort is eliminated.

The invention is illustrated in the drawing using an exemplary embodiment is illustrated, explained.

The circuit shown in the drawing represents part of a Television receiver is. In detail, the vertical deflection circuit for feeding the vertical deflection coil attached to the picture tube 28 and consisting of two sub-coils 27 and a power supply unit for generating the operating voltage -UB for the deflection circuit 0 There is a mains alternating voltage of 220V and 59 Hz. A mains transformer 3 is used to transform the high mains alternating voltage to a smaller value. The secondary winding of the network transformer 3 feeds a rectifier bridge 4, at whose output an unfiltered DC voltage appears. A capacitor 5 is used for the subsequent filtering of the mentioned direct voltage. The screened direct voltage obtained in this way is via a fuse 6 to a control circuit for stabilizing the appearing at the switching point 17 DC voltage -U B connected. The regulation takes place in a known manner by means of a series transistor 7, the base current of which flows through the resistors 8 and 9, wherein an auxiliary transistor 10 is a more or less conductive shunt for the said base current of the series transistor 7 forms. The more current through the auxiliary transistor 10 flows, the less base current flows into the series transistor 7, which thus so with increasing current through the auxiliary transformer 10 controlled less conductive will.

The auxiliary transistor 10 is used to compare one by means of a resistor 16 and a Zener diode 11 obtained reference voltage and one at the voltage divider tapped from the resistors 14 and 15, the output voltage at point 17 proportional Rule voltage. The opposing sand 12 and the diode 13 serve as a current limiting circuit. The circuit described so far causes that at point 17 by means of the as Potentiometer trained resistor l4 adjustable stabilized direct voltage -UB appears.

At point 17 there is a so-called ironless, i.e. without a deflection transformer working circuit for the vertical deflection of the television receiver with their Power supply connection connected. The control input of the deflection circuit is connected via a driver circuit 30 to a sync pulse source 31, see above that the output stage with the complementary transistors 24 and 25 synchronous with the image synchronization pulses derived in the receiver from the received video signal is operated. The output 29 of the output stage operating in a known manner is over a coupling capacitor 26 is connected to the deflection coil 27, in which during the A sawtooth-shaped deflection current is generated.

For the reasons described above, a constant Operating voltage -UB at point 17 for the output stage give rise to the problem that of this Operating voltage for both the sawtooth deflection circuit during the trace as well as the high pulse voltage would have to be applied during the retrace. To avoid doing this for the sawtooth deflection voltage during only a relatively small part of the operating voltage is available during the run-down time stands, the operating voltage is increased during the ramp-down time that the Output 29 of the deflection circuit according to the invention with one operating as a control input Point of the power supply is connected.

In the circuit shown zt the output 29 of the deflection circuit connected to the base of the series transistor 7 via an isolating capacitor 21. It can be seen that the negative appearing at output 29 during the return time tR Pulse voltage the series transistor 7 compared to the conductive state during the Follow-up time controls further conductive, so that the operating voltage -UB during the Duration of this negative voltage, i.e. during the retrace time tR from the value Uq . is increased to the value -UB2. During the run-out time tH has the operating voltage the value -UB1. Due to the aforementioned increase in the operating voltage during the ramp-down time tR, the negative pulse voltage at output 29 of the deflection circuit can be full form, without affecting the amplitude of the sawtooth-shaped deflection voltage significantly impaired during the run-out time.

Another possibility, directly in the control circuit of the power supply unit intervene, i.e. an increase in the operating voltage without any additional effort to be able to make is shown in dashed lines in the drawing. In the case, that the dashed circuit is used, the capacitor 21 containing Connecting line can be omitted. The negative pulse voltage at output 29 the control circuit is then via a circuit for polarity reversal and Via a separating capacitor 22 to the connection point of the resistors 14 and 15 connected. The occurrence of the positive pulse voltage during the flyback time to the voltage divider 14,15 causes a reduction in the case described Conductivity or blocking of the auxiliary transistor 10, so that an increased current or all of the current through resistors 8 and 9 into the base of the series transistor 7 can flow and thus controls the series transistor 7 to be conductive.

In order to ensure that any additional operating voltage UB connected consumers due to the pulse-shaped increase in the operating voltage are not interfered with during the return time, there is a decoupling resistor 18 provided, at the output of which a filter capacitor 19 is connected. At the clamp 20 appears when the capacitance value of the capacitor 49 is sufficiently large Equalization, which is almost free of the tension jumps at the switching point 17. Uer decoupling resistor 18 ensures that the capacitor 9 has the desired Voltage jumps at point = 7 not affected.

For the inventive coupling of the output of the deflection circuit A power supply unit with thyristors is advantageously suitable for the control circuit of the power supply unit, in which the power consumption when the output voltage changes because of the pure Switching action of the thyristors is very low.

Claims (2)

Patent claims 1. Circuit arrangement for the deflection of an electron beam in a cathode ray tube with a deflection coil located in the output circuit of the output stage, at which a high return pulse voltage during the return time of the electron beam occurs, the operating voltage for the output stage during the ramp-down time has a higher value than during the trace time, especially for the vertical deflection in a television receiver, characterized in that the operating voltage is the Output voltage (-U> an electronically regulated voltage source that is provided with a control input that as a control voltage for the voltage source a voltage derived from the flyback pulse voltage is used, and that the control input the voltage source is connected to its control circuit. 2. Circuit arrangement according to claim l, characterized in that a decoupling element (18) to connect additional consumers to the voltage source is provided, the output of which is connected to a reference voltage via a filter capacitor (19) connected.