DE3009353C2 - - Google Patents

Description

The behavior is when you turn off a television receiver of the electron beam immediately after switching off in many cases undefined. When the distraction subsides quickly and remaining high voltage it can become a light spot come, which burns in the long run and the picture tube unusable makes. It can also last a long time after being switched off an undesired glow of the screen due to residual charges arise. Such phenomena can for the Picture tube harmful or disruptive or uncomfortable for the viewer Act.

It is known in particular in the case of black and white television receivers (DE-PS 11 60 002), by an additional circuit immediately after switching off the receiver, the beam current increases sharply increase so that the high voltage source is quickly discharged even before the distraction subsides. Such circuits have especially the purpose of stopping the high voltage for a long time due to the good insulation of the surface to avoid the picture tube.  

It is also known in particular for color television receivers (DE-OS 27 19 146), between the high-voltage connection Picture tube and earth to turn a load resistor on the capacitor carrying the high voltage when switching off discharges quickly. This resistance becomes general referred to as "bleeder".

There was also a circuit for dark control of the picture tube proposed (P 29 10 155), in which the line return pulses increased to a first operating voltage and via an RC parallel link applied to the control electrode of the picture tube are the one for the reverse pulses in the reverse direction polarized diode with a second operating voltage or earth connected is. Such a circuit requires for the RC parallel link a capacitor with a relatively high capacitance in the order of 2 µF. Such a capacitor must generally be an electrolytic capacitor. Such However, capacitors are in practice because of their cost undesirable.

In a television receiver must be independent of this dark control a relatively high screen grid voltage for the picture tube of approximately 680 V. Since the power supply Generally does not provide operating voltage of this size, it is known to rectify this screen grid voltage the line return pulses to gain an amplitude in the order of 1000 V. To do this are a Rectifier, a charging capacitor and a filter circuit required.

The invention has for its object a circuit for Dark tube control to create that with less Components get along as the known circuits and in particular the use of a capacitor of lower capacitance enables.  

This object is achieved by the invention described in claim 1 solved. Advantageous further developments are in the Subclaims described.

In the solution according to the invention, the filter capacitor is therefore used more advantageous for screening the screen grid voltage Way also used as the capacitor whose Voltage when the receiver is switched off or when the Distraction causes the dark control of the picture tube. Since the connected resistor networks must be of high impedance can, the capacitance of the capacitor may be correspondingly lower be sized, e.g. B. only 0.22 µF. The ones needed two circuits previously implemented separately for the generation of the screen grid voltage and for the Dark control of the picture tube are thus more skillful Combined in the sense of saving components.

The invention is based on the drawing of an embodiment explained. It shows

Fig. 1 is a schematic diagram of the invention and

Fig. 2 shows curves for explaining the operation of the circuit of FIG. 1.

In Fig. 1, a positive voltage U 4 is obtained from the line return pulse 1 with the resistor 2 , the diode 3 and the capacitor 4 . The amplitude of pulse 1 is approximately 1200 V peak-peak. The point c carrying the voltage U 4 is connected on the one hand via the resistors 5, 6 to the Wehnelt electrode 7 of the picture tube 8 and on the other hand via the resistors 9, 10 to the operating voltage (U 1 ) of 150 V taken from the power supply . The screen grid voltage Ug 2 for the picture tube 8 is taken from a tap of the resistor 9 , sieved with the screen member 11, 12 and fed to the screen grid 14 of the picture tube 8 via the resistor 13 . The connection point b of the resistors 5, 6 is connected via the diode 15 to the positive operating voltage U 3 of +12 V. In FIG. 2, the steady ON state is represented by t1. Due to the positive voltage U 4 , a current flows through the resistor 5 and the diode 15 , which keeps the diode 15 conductive. As a result, the point b for AC voltage is practically grounded, so that the filter element 11, 12 is as effective as if the upper end of the capacitor 12 , namely its base point, were connected to earth. The positive screened voltage of 680 V at point a is thus effective on the screen grid 14 . At point b there is a voltage of U 3 = 12 V because the diode is always permeable. The circuit shown does not effect a return blanking because the pulse 1 does not reach the picture tube 8 . At time t 1 , the receiver is switched off. As a result, the voltage at point a breaks down very quickly to 0. However, the voltage U 2 across the capacitor 12 initially remains with the polarity shown, because the capacitor 12 cannot discharge as quickly because of the connected high-impedance resistors. This means that the voltage at point b changes very quickly and strongly in the negative direction. As a result, a reverse voltage now reaches the Wehnelt electrode 7 , which brings about the desired dark control of the picture tube. This voltage change is possible through the diode 15 , which is blocked by the falling voltage at point b . The blocking of the picture tube 8 takes about 3 s, which is sufficient for practical cases for discharging the high voltage via a bleeder.

If there is no deflection or other failure of the return pulse 1 , the high positive voltage U 4 does not arise or is eliminated. Then the picture tube 8 is also dark-controlled in the desired manner, because then the voltages at the electrodes 7, 14 necessary for the bright control of the picture tube no longer occur. In a preferred embodiment of the invention, the individual components had the following values: R 2 : 15 kOhm C 4 : 10 nF R 5 : 2 MOhm R 6 : 1 kOhm R 9 : 1 MOhm R 10 : 820 kOhm R 11 : 470 kOhm C 12 : 0.22 µF R 13 : 10 kOhm.

The circuit according to the invention has the following advantage. As already described, the screen grid voltage Ug 2 drops very rapidly at point a at time t 1 . This reduction in the screen grid voltage Ug 2 additionally means that the picture tube 8 is blocked. The desired blocking of the beam current in the picture tube 8 at the moment of switch-off t 1 is thus further supported by the rapid drop in the screen grid voltage Ug 2 . This blocking of the beam current is particularly important for the period in which the high voltage is reduced by the bleeder, which is mentioned in the introduction, so that the picture tube does not light up without deflection and the beam damages the screen.

Claims (3)

1. Circuit for dark control of the picture tube in a television receiver when switched off and in the absence of distraction by applying a blocking voltage to a brightness control electrode of the picture tube, on which there is also a screen grid voltage screened with an RC filter element, characterized by the following features:

• a) the base of the filter capacitor ( 12 ) is connected to a reference voltage (U 3 ) or ground via a diode ( 15) which is polarized permeable to the screen grid voltage (Ug 2 ), b) a positive voltage obtained by rectifying the line return pulses ( 1 ) ( U 4 ) is connected via resistors ( 9, 5 ) to the input of the filter element ( 11, 12 ) and to the connection point (b) of filter capacitor ( 12 ) and diode ( 15 ),
• c) said connection point (b) is connected to the brightness control electrode ( 7 ).

2. Circuit according to claim 1, characterized in that the resistors ( 5, 11 ) are in the order of 0.5-2 MOhm. 3. A circuit according to claim 1, characterized in that the input of the filter element ( 11, 12 ) is connected to the tap of a resistor ( 9 ) which lies between the positive voltage (U 4 ) and a further operating voltage (U 1 ).