DE2218058A1 - CIRCUIT FOR STABILIZATION OF HIGH VOLTAGE FOR THE DEFLECTION SYSTEM OF A CATHODE BEAM TUBE - Google Patents

Description

Circuit to stabilize the high voltage for the deflection system of a cathode ray tube The invention relates to a circuit for stabilization that obtained from an additional winding of the transformer of a line deflection stage High voltage for the deflection system of a cathode ray tube, especially in one Television receiver.

For generating the anode voltage of a cathode ray tube in a television receiver, the values of which usually range up to 25 kV, is known an additional winding of a transformer is used in the line output stage. In a such a circuit for generating a high voltage is the during the line retrace, i.e. occurring in a very short time and associated with a change in sign Transition of the deflection current between its maximum values used. The through this A high return voltage induced by a current change is generated via the auxiliary winding Rectifier cascade supplied, which serves as a voltage multiplier.

Since the high voltage is obtained directly in the line output stage and e.g. changes in the operating voltage and load changes in the line output stage affect the amplitude of the flyback voltage is also the magnitude of the high voltage depends on the changes in the sizes mentioned. It is known for example (DT-AS 1 537 572), the well-known pillow-shaped or barrel-shaped raster distortions in a Television receiver to eliminate the fact that the operating savings for the line output stage in the rhythm a parabolic control voltage derived from the vertical deflection voltage is modulated.

The modulation of the operating voltage for the line output stage causes but also a modulation of the high voltage obtained in the line output stage. Fluctuations the high voltage amplitude have a detrimental effect on brightness and sharpness of the television picture, and in the case of a color television receiver, the color purity is additionally worsened.

It is also known that, in the reverse direction, e.g.

indirectly by changing the brightness of a television receiver a change in the high voltage caused by changing the beam current is disadvantageous affects the constancy of the amplitude of the line deflection current.

For the reasons mentioned, it is desirable to use the high voltage stabilize. For the latter case, where there is a change on the high voltage side influences the amplitude of the line deflection current by changing the beam current, several circuits for stabilizing the high voltage are known (Koubek "Fernsehempfangstechnik", Munich 1969, page 394 - page 399). For example, it is known when there is a change of the beam current in a complicated pulse shaper circuit the steepness of the To change control pulses for the line output stage, in this way the from the rate of change of the current in the line output stage dependent amplitude to change the high voltage. Another known circuit is parallel a ballast tube connected to the anode of the picture tube, each connected to the one from the picture tube takes over unneeded high-voltage power. These known circuits are but not suitable for the other case in which the modulation of the operating voltage an undesired change in the high voltage is caused for the line output stage.

The invention is based on the object of creating a circuit with which the high voltage is stabilized in a simple way and those mentioned for all Cases is applicable.

The invention relates to the circuit mentioned at the beginning.

The circuit according to the invention is characterized in that the one end of the additional winding instead of a constant reference voltage to an auxiliary voltage is connected, the size of which is synchronized with that influencing the high voltage Disturbance variable and out of phase with the change caused by the disturbance variable the high voltage changes.

Further developments and advantageous embodiments of the invention are described in the subclaims and in the description.

The invention is based on an exemplary embodiment shown in the drawing is illustrated, explained. 1 shows a circuit according to the invention for Stabilization of the high voltage and FIG. 2 shows a circuit according to a further development the invention.

In Fig. 1 is a circuit for the ¼ horizontal deflection (line deflection) of a television receiver. The circuit contains a line output stage with an output stage transistor 10 and a flyback transformer 11. The Zei3e, nendstuze serves to feed a deflection coil 8.

The circuit shown in Fig. 1 also contains a high voltage part with an additional winding 13 of the flyback transformer serving as a high-voltage winding 11 and a rectifier cascade 17 for generating a signal that can be tapped off at the output 18 High voltage. The line end stage is constructed as follows. From the on the terminal 1 applied mains AC voltage is by means of the rectifier 2 and the charging capacitor 3 generates a DC voltage that is applied to the input of a regulated and controllable Power supply unit 4 is connected. A voltage appears at the output of the power supply unit 4 the is stabilized against undesirable influences and their value is at the same time in rhythm a control voltage applied to the control input 5 of the power supply 4 via terminal 6 is controlled. The output voltage of the power supply 4 is used to power a Control circuit 7 for controlling the output stage transistor 10 and also for the power supply the line output stage with the output stage transistor 10.

The control circuit 7 contains an oscillator and one or more Driver stages; it is constructed so that the changes in the output voltage of the Power supply 4 according to the control voltage at terminal 6 has no adverse effect on the output signal of the control circuit 7. The collector of the with his The base of the transistor 10 connected to the output of the control circuit 7 is Via the primary winding 12 of the flyback transformer 11 to the output voltage of the Power supply unit 4 connected, while the emitter of transistor 10 is connected to ground (reference voltage) lies. The collector of transistor 10 is via a flyback capacitor 14 as well connected to Hasse. The deflection coil 8 to be fed by the line output stage is on the one hand via a capacitor 9 to the collector of the transistor 10 and on the other hand connected directly to ground.

The circuit described so far works in a known manner the principle of current recovery, whereby the collector-base path of the transistor 10 operated inversely during the return time of the deflection current in the deflection coil 8, i.e. is opened and thus performs the function of the known recovery diode. The deflection current in the deflection coil 8 consists of a long sawtooth-shaped part during the line trace and a subsequent half cosine oscillation during of the short return line. In order to avoid the unwanted pillow or to eliminate barrel-shaped raster distortions in the direction of the image line, is the output voltage of the power supply unit 4, i.e. the operating voltage for the line output stage parabolic modulated (parabolic control voltage at terminal 6 or at the Control input 5 of the power supply unit 4).

The flyback transformer 10 has a secondary winding Additional winding 13, by means of which the for the generation of the electron beam in the cathode ray tube the television receiver required high voltage is obtained. Here the great rate of change of the deflection current used during the line return. A rectifier cascade 17 is provided for rectifying this high voltage, which also works as a multiplier circuit. At the output 18 of this circuit a rectified high voltage can be tapped.

When the lower end of the auxiliary winding 13 of the flyback transformer 11 were connected to ground, as is customary, the output voltage would be modulated of the power supply unit 4 also cause a modulation of the high voltage at the output 18 at the same time.

To prevent this undesirable modulation of the high voltage, is the lower end of the high-voltage winding 13 according to the invention not to ground but connected to an auxiliary voltage at point 25, which corresponds to the high voltage at the Additional winding 13 is added.

The auxiliary voltage at point 25 is obtained as follows. To the Unregulated DC voltage obtained by means of the rectifier 2 and the charging capacitor 3 the input of an auxiliary power supply 23 is connected, the output voltage of which is about a control input 24 can be controlled. The auxiliary power supply 23 is constructed so that an increase in the voltage at the control input 24 a decrease in the output voltage of the auxiliary power supply 23 causes.

The output voltage of the auxiliary power supply 23 is used for power supply the series connection of a coil 20 and a capacitor connected to ground 19, which is bridged by a diode 16.

The connection point 25 between the coil 20 and the capacitor 19 is via a further diode 15 to the collector of transistor 10 of the line output stage connected.

The circuit described so far works in the same way as the line output stage with the transistor 10 according to the principle of current recovery. From the function here the coil 20 corresponds to that in FIG the line end stage are effective Inductance, the capacitor 19, the recovery capacitor 14 and the diodes 15 and 16 to the transistor 10 operated as a switch. The control of the base of the transistor 10 by means of the control circuit 7 corresponds to the additional circuit with the coil 20 the control of the diode 15 by means of the collector voltage of the Transistor 10. By periodically switching the coil 20 on and off by means of the Diode 15 to ground (reference voltage) is switched on during line retrace, i.e. when the Diode 15 is blocked at point 25 according to the return voltage at the collector of the transistor 10 generates a pulse voltage. The amplitude of this voltage is depending on the output voltage of the auxiliary power supply 23, so that it is via the control input 24 of the auxiliary power supply 23 is controllable, which is connected to the tap of one of the resistors 21 and 22 existing voltage divider is connected. The said voltage divider 21, 22 is connected to the output terminal 18 of the high-voltage part, so that the output voltage of the auxiliary power supply 23 is reduced, e.g. when the high voltage rises will. A reduction in the output voltage of the auxiliary power supply 23 in turn causes a reduction in the auxiliary voltage generated at point 25, so that in said Case the sum of the increased high voltage on the additional winding 13 and the reduced auxiliary voltage at point 25 remains constant. You can see that the shown Circuit forms a control loop to stabilize the high voltage. For stabilization of the high voltage, it is irrelevant whether there is a disturbance in the high voltage of the line output stage or the load connected to terminal 18 comes.

Since the output voltage of the power supply unit 4 is constant on average, can the reference voltage for the auxiliary power supply 23 can be derived from it by sieving.

A further development of the invention is shown in FIG. Same Reference numerals in Figure 1 and Figure 2 mean that the relevant components perform the same function in both circuits.

In contrast to the circuit of Figure 1, the primary winding 12 of the flyback transformer 11 in Figure 2 not directly to the output of Power supply 4 connected, but via a Schutzw åerstana 28, which in the event of a fault prevent destruction of the line-end transistor by too high a current target. Since the amplitude of the deflection current through the line output stage z.3. at change of the beam current in the cathode ray tube could change, this would also change the voltage falling across the resistor 28 and thus a change in the actual voltage Mean operating voltage of the line output stage. To this, at the connection point between the resistor 28 and the primary winding 12 of the flyback transformer 11 to keep the lying voltage constant with a change in the deflection current, is the voltage divider consisting of the resistors 35 and 36 for the voltage comparison between the voltage to be regulated and a reference voltage not directly to the Output of the power supply 4 but to the end facing away from the output of the power supply 4 of the resistor 28 connected. At the tap of the voltage divider from the resistors 35 and 36, the base of an auxiliary transistor 33 in the power supply unit 4 'is connected, its Emitter via a diode 37 with one provided for generating the reference voltage Zener diode 34 is connected and its collector in a known manner the Begel transistor 32 of the power supply 4 controls.

The emitter of the auxiliary transistor 33 is also via a capacitor 38 is connected to the control input 5 of the power supply unit 4, to which the control voltage for the modulation of the output voltage.

In order to prevent that when switching on the power supply unit 4, an excess the output voltage and thus a risk to the line output stage occurs the control voltage supplied via the capacitor 28 via the diode 37 to the The potential of the reference voltage on the Zener diode 34 is clamped. By this measure it is also possible to adjust the amplitude of the line deflection independently of the equalization adjust the raster distortion.

Another difference to the circuit of Figure 1 is that Circuit according to Figure 2 in that the voltage divider from the resistors 21 and 22 for controlling the control input 24 on the auxiliary power supply 23 not directly is connected to the output terminal 18 for the high voltage, but a part des for focusing the electron beam in the cathode ray tube required voltage divider forms. For the aforementioned focusing you need not the full high voltage at the output 18 of the multiplier circuit 17, but just a much lower tension. This is why this is for recruitment the potentiometer 26 provided at the terminal 27 that can be tapped off connected to the first possible output of the multiplier circuit 17. There the high voltage tapped here is much lower than that at the output terminal 18 appearing high voltage, the resistors 21 and 22 need with regard to the High voltage resistance does not meet such high requirements as in the circuit according to Figure 1.

Finally, the circuit shown in FIG. 2 differs of the circuit shown in Figure 1 still in the arrangement and connection the inductance required to obtain the auxiliary voltage (20 in Fig 1). To the auxiliary voltage generated at the node 25, which corresponds to the above Explanations of the high voltage applied to the additional winding 13 are added, to increase to a value that cannot be achieved with the arrangement according to FIG is, a winding part 30 of an autotransformer is used in Figure 2 for said inductance 29 used. The increase in the auxiliary voltage is advantageous when the The high voltage range exceeds the control range of the auxiliary voltage.

The autotransformer 29 is between the output of the auxiliary power supply 23 and the cold end of the high-voltage winding 13 of the flyback transformer 11 switched. A tap of the autotransformer 29 is connected to the circuit point 25 connected. The winding part 30 of the autotransformer 29 works like the coil 20 in Figure 1. Corresponding to the transmission ratio between the winding 30 as well as the sum of windings 30 and 31, i.e. the total winding of the autotransformer 29, the auxiliary voltage generated at the winding part 30 is stepped up. the The auxiliary voltage increased in this way ultimately becomes the voltage on the high-voltage winding 13 added. The enlarged, at the ends of the autotransformer 29 lying auxiliary voltage allows the high voltage over a correspondingly larger To readjust the area.

The high voltage stabilized with the circuit according to the invention can advantageously be used to control a phase comparison circuit, which is provided for the synchronization of the line deflection. In this phase comparison circuit the phase of the flyback voltage of the line output stage becomes the phase of the synchronous sierimpulse compared to the video signal coming from the transmitter.

Fluctuations in the amplitude of the flyback voltage result in errors in the output voltage of the phase comparison circuit. One directs the for the phase comparison required return voltage from the stabilized high voltage, e.g. by means of another winding of the flyback transformer or by means of a voltage divider, this gives return pulses with a constant amplitude.

Claims (7)

PATENT CLAIMS Circuit for the stabilization of an additional winding of the transformer a line deflection level gained high savings for the deflection system of a cathode ray tube, in particular in a television receiver, characterized in that one end the additional winding (13) instead of a constant reference voltage to an auxiliary voltage is connected, the size of which is synchronized with that influencing the high voltage Disturbance and out of phase with the change caused by the disturbance itself High voltage changes. 2. A circuit according to claim 1 for a current recovery principle working line output stage, characterized in that for generating the auxiliary voltage a circuit that also works on the principle of power recovery one to the output voltage of an auxiliary power supply (23) and an electronic one Switch to the inductance (20) connected to the reference voltage is provided, the electronic switch in a manner known per se from a recovery capacitor (19) is bridged and the control input of the electronic switch is on one of the control voltage for the electronic switch of the actual line output stage derived control voltage is connected, and that the auxiliary voltage is connected to the switch-side The end of the inductance (20) can be tapped, and that the auxiliary power supply (23) has a Control input (24) can be controlled, which is connected to a voltage influenced by the disturbance variable connected. 3. A circuit according to claim 2, characterized in that the electronic Switch for generating the auxiliary voltage from a first and a second Diode consists that the first diode (16) between the inductance (20) and the reference voltage is connected that the second diode (15) between the inductance (20) and the collector of the as an electronic switch for the line end stage serving transistor (10) is arranged, wherein the second diode (15) is polarized is that they are for one through the inductance (20) and the collector-emitter path of the transistor (10) flowing current is permeable, and that the first diode (16) with respect to the current through the inductance (20) is polarized in reverse as the second diode (15). 4. A circuit according to claim 2, characterized in that the control input (24) of the auxiliary power supply connected to the tap of a voltage divider (21, 22) is connected to the high voltage leading end of the additional winding (13) is. 5. A circuit according to claim 2, characterized in that as a reference circuit for the auxiliary power supply (23) one of the output voltage of the power supply (4) for the Line output stage derived and screened voltage is used. 6. The circuit of claim 1 for a line output stage that has a Resistor connected to the output voltage of the power supply unit for the line output stage is, wherein the power supply is controllable, characterized in that one in the power supply (4) per se for comparing the output voltage of the power supply unit (4) with a reference voltage provided circuit instead of the output voltage of the power supply unit (4) with the resistor (28) is connected. 7. A circuit according to claim 2, characterized in that, the da13 Inductance (20) is designed as part of an autotransformer (29) whose entire winding between the output voltage of the auxiliary power supply (23) and the additional winding (13) is arranged and its tap is connected to the recovery condenser (19) is.