DE2262651A1 - CIRCUIT FOR STARTING AN AUXILIARY VOLTAGE SOURCE, WHICH IS SUPPLIED BY THE OUTPUT VOLTAGE OF A DEFLECTION CIRCUIT - Google Patents

Description

Circuit for starting an auxiliary voltage source from the output voltage a deflection circuit is fed.

The invention relates to a circuit for starting an auxiliary voltage source, that of the output voltage of a deflection circuit for a cathode ray tube is fed and used as the operating voltage for a deflection circuit driving Control circuit is used, in particular for a television set, in which the operating voltage of the line oscillator is obtained from the trace pulses of the line output stage.

When using a high DC operating voltage of e.g.

150 to 200 volts for the output stage of the horizontal deflection circuit The television receiver is required to supply power to the one controlling the horizontal output stage Horizontal oscillator an auxiliary voltage source with a low DC output voltage of e.g. 10 to 20 volts. This low supply voltage for the horizontal oscillator is in a construction of a circuit for the horizontal oscillator with such transistors not required for a connection to the high operating voltage mentioned are suitable. The lower supply voltage for the horizontal oscillator is especially necessary if integrated circuits for this circuit be used.

It is known (DT-OS 2 050 495), instead of a separate power supply unit, a winding of the flyback transformer to use, via which the flyback pulses of the horizontal output stage to a rectifier and a charging capacitor. To start this auxiliary voltage source, which is when the deflection circuit is switched on because of not yet having an operating voltage supplied and therefore not yet oscillating horizontal oscillator itself can build, is a series circuit of a capacitor in the known circuit and a diode provided between the operating voltage for the horizontal output stage and the auxiliary voltage source is connected, wherein between the connection point of capacitor and diode on the one hand and ground on the other hand a load resistance is switched for the capacitor. When switching on the operating voltage for the The horizontal output stage is powered by the horizontal oscillator via the capacitor supplied so that the horizontal oscillator begins to oscillate and thus the generation the auxiliary voltage starts up via the flyback pulses of the horizontal output stage. After the auxiliary voltage has built up, the diode blocks automatically, so that the auxiliary voltage source is disconnected from the capacitor and the resistor. This circuit to start the auxiliary voltage source fails when the increase in the operating voltage for the Horizontal output stage goes so slowly after switching on this voltage, that the mentioned capacitor, which can only transmit voltage changes, does not can supply enough current to supply the horizontal oscillator.

The invention is based on the object of creating a circuit which avoids the difficulty mentioned and with a low level of circuitry Effort can be realized.

The invention relates to the circuit mentioned at the beginning.

the circuit according to the invention is characterized in that the circuit point at the emitter which forms one pole of the auxiliary voltage source an auxiliary transistor is connected, the collector of which is connected to the operating voltage and its base to the tap of a voltage divider fed by the operating voltage is connected that in the current path for the through the auxiliary transistor to the control circuit flowing supply current is arranged a diode path that the control circuit remote electrode of the diode path connected to a bias voltage dimensioned in this way is that the diode path is automatic after starting the auxiliary voltage source Is blocked.

The invention is based on two exemplary embodiments that are shown in FIG Drawing are shown, explained.

1 shows a circuit according to the invention and FIG. 2 shows an advantageous one Application example of the circuit according to the invention.

Fig. 1 shows a circuit as a partial circuit of a television receiver for the horizontal deflection of the television receiver. The picture tube 17 of the television receiver is provided with a deflection coil consisting of two sub-coils 18, which is of a Horizontal output stage with an output stage transistor 15 with a sawtooth-shaped Deflection current is fed.

The output stage containing the output stage transistor 15 reworks the well-known system of electricity recovery. The one for controlling the output stage transistor 15 required horizontal frequency control voltage is provided by an oscillator 7 generated and amplified by a driver stage 9. The output of driver stage 9 is connected to the base of the output stage transistor 15. The driver stage 9 is working essentially operating as a horizontal frequency switch. In the working group of the output stage transistor 15 is the Primary winding 12 of a deflection transformer 11, which has two secondary windings 13 and 14. Instead of one at one at a time Principle of the current recovery circuit using the usual recovery diode, which would have to be connected in parallel to the recovery capacitor 16, the circuit shown uses the collector-base path of the output stage transistor 15, which is operated inversely for a certain time in each deflection period. To the collector current occurring during the inverse operation of the output stage transistor 15 of the output stage transistor 15 to be able to flow into the base of this transistor, contains the driver stage 9 a corresponding current path, for example from an between the output of the driver stage 9 and ground connected diode can exist (not shown).

For coupling the deflection coil 18 to a tap on the primary winding 12 of the deflection transformer 11 is a parallel circuit of one as a linearity controller used coil 21 and a resistor 20 and one in series with this parallel connection lying capacitor 19 is provided. The components mentioned cause an equalization and correction of the deflection current. For the generation of the operation of the picture tube 17 required high voltage is the secondary winding 13 of the deflection transformer 11 is provided, the output voltage of which is rectified by means of a diode 25 and which can be tapped at terminal 26.

A source is used to supply power to the circuit shown 1 with an operating voltage + U. Since this DC voltage + U = a relatively high Has a value of e.g. 200 volts, and there is the control circuit for the horizontal output stage (Oscillator 7 and driver stage 9) only on one for the reasons mentioned above The deflection transformer has a small DC operating voltage 11 the secondary winding 14, the output voltage of which is rectified by a rectifier 22 will. The rectified Voltage is provided by a capacitor 23 and is available at terminal 24 to operate other circuits such as e.g.

the vertical deflection circuit available. Terminal 24 is still there Connected via a diode 10 to a circuit point 8 to which the power supply connections the control circuits (oscillator 7 and driver stage 9) are connected. That Transformation ratio between the primary winding 12 and the secondary winding 14 of the deflection transformer 11 is dimensioned so that the occurring at node 8 DC voltage is not greater than that required for the circuits mentioned Value. The requirement that the control circuits only operate with a small one voltage can be operated, is justified, for example, by the fact that for these circuits Integrated circuits are used that are not used for the output stage transistor 15 feeding high DC operating voltage are suitable.

Dx Diode 22 for rectifying the output voltage of the secondary winding 14 of the deflection transformer 11 is polarized so that to generate the at the terminal 24 tapped direct voltage only the trace pulses of the horizontal output stage are used.

It can be seen that the circuit described so far does not work by itself can start. The auxiliary circuits (oscillator 7 and driver stage 9) can initially can only be supplied with a DC operating voltage if in the deflection transformer 11 the. mentioned trace pulses occur. But this is only the case if the oscillator 7 oscillates.

To enable the described circuit to start up properly, an auxiliary transistor 5 is provided, the collector of which is connected via a resistor 4 the DC operating voltage + U is connected. The base of the auxiliary transistor 5 is to one between the DC operating voltage + U and ground arranged voltage divider from the resistors 2 and 3 connected. The emitter of the auxiliary transistor 5 is connected to the node 8 and via a Filter capacitor 6 connected to ground.

The circuit described so far for starting the operating voltage of node 8 operates as follows. When switching on the DC operating voltage + U appears at the emitter of the auxiliary transistor 5 that of the resistors 2 and 3 existing voltage divider also set the base voltage at the emitter of the Auxiliary transistor 5. As a result, the oscillator 7 and the driver stage 9 become the same supplied with operating current after switching on the DC operating voltage + U. if the oscillator 7 has started to oscillate, the terminal 24 also appears Auxiliary voltage obtained from the trace pulses of the deflection transformer 11. There the base bias of the auxiliary transistor 5 is selected to be smaller than that at the terminal 24 tapped auxiliary voltage is the diode 10 after the build-up of the voltage on the Terminal 24 conductive, so that at node 8 after starting the entire circuit the voltage of terminal 24 also appears. As this tension - as above Provided-is greater than the base voltage of the auxiliary transistor 5, the Base-emitter path 39 and thus the auxiliary transistor 5 itself are automatically blocked. The diode 10 prevents the auxiliary transistor 5 from except during the starting process the oscillator 7 and the driver stage 9 also the others to the terminal 24 connected circuits of the television receiver must supply. For the startup process it is sufficient if initially only the oscillator 7 and the driver stage 9 have operating voltage are supplied.

In Fig. 2 is an advantageous application example of the invention Circuit according to Fig. 1 shown. While assumed in the circuit of FIG becomes that a DC operating voltage is present, is in Fig. 2 in addition for the horizontal output stage according to FIG. 1, a power supply unit for generating such a DC operating voltage shown. The alternating mains voltage applied to terminal 28 is supplied by a rectifier 27 rectified and filtered by a charging capacitor 29. In series with the rectifier 27 a protective resistor with a small resistance value of e.g. 10 ohms can be connected be. To stabilize or regulate the DC voltage obtained in this way, a between the output of the charging capacitor 29 and that of the horizontal output stage formed load arranged control transistor 32 is provided.

A control transistor 37 is used to control the regulating transistor 32 provided, the emitter of which is connected to a comparison voltage which is determined by means of a Zener diode 38 fed via a resistor 40 is obtained. The base of the control transistor 37 is connected to a voltage divider from the resistors 34 and 35 connected, which is arranged between the output of the control transistor 32 and ground is. By means of the voltage divider from the resistors 34 and 35, the respective Control voltage measured at the output of the control transistor 32 and with the comparison voltage at the Zener diode 38 compared. Which depends on the difference between Control voltage and reference voltage more or less conductive controlled control transistor 37 forms the base current of the control transistor flowing through a resistor 31 32 a more or less conductive shunt. It can be seen that the described Circuit represents a power supply operating in the usual way. At output 41 dx3es In the power supply unit, a capacitor can be connected to ground as protection against vibrations be.

In the circuit shown in FIG. 2, according to a development the invention of the already existing control transistor 37 as an auxiliary transistor 5 utilized in the circuit of FIG.

For this reason, the emitter of the control transistor 37 is via a Diode 39 connected to circuit point 8.

When the AC mains voltage U is switched on, the auxiliary circuits (Oscillator 7 and driver stage 9) first of all via resistors 31 and 36 and the transistor 37 and the diode 39 fed. After the oscillator has started to oscillate 7, the operating voltage is built up at terminal 24, so that the voltage at the switching point 8 is determined by the voltage at terminal 24. During the start-up process is the voltage at the node 8 first depends on the Zener voltage of the Zener diode 38 determined, the value of which corresponds to the base voltage of the auxiliary transistor 5 in the The circuit according to FIG. 1 is chosen to be somewhat smaller than the fully developed operating voltage at terminal 24.

It can be seen that in the circuit according to FIG. 2 it is not possible the control transistor 37 and the auxiliary transistor 5 in the circuit of FIG the start to block, since the control transistor 37 then its actual functions as a control transistor can no longer exercise. That is why the diode is 39 provided, which is biased by the Zener voltage of the Zener diode 38 and the when the voltage rises at terminal 24 and thus at circuit point 8 to the Value of the Zener voltage of the Zener diode 38 is automatically blocked. The diode 39 takes over at the end of the starting process in the circuit according to FIG. 2 the FunkffDn of the base-emitter path of the auxiliary transistor 5 in FIG. 1.

About the behavior of the circuit described so far during the starting process Still to be improved, a resistor 30 is connected in parallel with the regulating transistor 32. Furthermore, between the Control voltage and the resistor 36 a diode 33 switched.

The diode 33 is polarized so that after switching on the AC mains voltage at the terminal 28 a current through the resistor 30 and the diode 33 in the during the starting process as an auxiliary transistor corresponding to the auxiliary transistor 5 of the circuit 1 operating control transistor 37 can flow. So the resistance needs 31 not to be dimensioned in such a way that it has the entire starting current for the auxiliary circuits (Oscillator 7 and driver stage 9) must apply. In normal operation the diode is 33 locked, so that they control the function of the control transistor 37 with respect to the Control transistor 32 does not interfere.

33 The diode enables the horizontal output stage to be protected too high a control voltage in the event that the horizontal output stage fails. This risk of a zhohan control voltage in the case mentioned arises because that the resistor 30 is present. Although the control transistor 32 is during the blocked in the event of a malfunction; but since the resistor 30 is present, can the DC voltage at the output of the charging capacitor 29 via 41 the resistor 30 to the voltage terminal for the horizontal output stage. To the for the said In the event that the control voltage occurs, it is necessary to keep it as small as possible the resistor 30 to take a load current, the voltage drop across the resistor 30 generated, and thus the control voltage compared to the output voltage of the charging capacitor 29 significantly reduced. Since in the case mentioned (failure of the horizontal output stage) there are no pulses in the deflection transformer and therefore no operating voltage can arise at terminal 24, diode 39 is seen from circuit point 8 no longer preloaded in the blocking direction. This has the consequence that. over the resistance 30 and the then current-conducting diode 33 as well as the then also current-conducting transistor 37 an operating current into the Auxiliary circuits (oscillator 7 and Driver stage 9) can flow.

The mentioned auxiliary circuits then load the resistor 30, so that there is a voltage drop across it, which at the same time indicates by what amount the control voltage is smaller than the output voltage of the charging capacitor 29.

Claims (4)

P a t e n t a n g e r u c h e Circuit for starting an auxiliary voltage source from the output voltage an Ablen] ccircuit for a cathode ray tube is fed and used as the operating voltage is used for a control circuit driving the deflection circuit, in particular for a television set, in which the operating voltage of the line oscillator from the trace pulses the line output stage is obtained, characterized in that the one pole the circuit point (8) forming the auxiliary voltage source at the emitter of an auxiliary transistor (5,37) is connected, its collector to the operating voltage (+ U) and its Base to the tap of a voltage divider fed by the operating voltage (+ U) (2,3) is connected that in the current path for the through the auxiliary transistor (5,37) to the control circuit (7,9) flowing supply current a diode path (39) it is arranged that the electrode of the diode path facing away from the control circuit (7, 9) (39) is connected to a preload dimensioned in such a way that the DidEn stretch after is automatically blocked when the auxiliary voltage source is started. 2. Circuit according to claim 1, characterized in that the diode path (39) is formed by the base-emitter-Strecle of the auxiliary transistor and that as Bias voltage for the diode path tapped at the voltage divider (2,3) Voltage is used (Fig. 1). 3. A circuit according to claim 1, characterized in iß as the operating voltage the output voltage of a controllable power supply is used, in which the control transistor (32) is controlled by a control transistor (37), the collector of which is connected to the regulated (41) and / or connected to the unregulated operating voltage is and its base to the tap of one of the regulated operating voltage (41) fed Voltage divider (34,35) is connected that the control transistor (37) during the starting serves as an auxiliary transistor and that the emitter of the control transistor (37) via a diode (39) forming said diode path to which the auxiliary voltage forming node (8) is connected (Fig. 2). 4. Circuit according to claim 3, characterized in that in parallel a resistor to the control transistor (32) connected in series with the deflection circuit (30) is arranged that the output of the control transistor (32) via a polarized further diode path (33) connected to the collector of the control transistor (37) is that when the output voltage (41) increases above a predetermined value the further diode path (33) is conductive (Fig. 2).