DE1160002B - Circuit arrangement for protecting the luminous layer of the picture tube in a television receiver - Google Patents

Description

When switching off television receivers, there is a risk that the beam current of the picture tube will last longer remains as the deflection and the resulting light spot on the screen of the picture tube can burn in. This danger is particularly great because the high voltage because of the high quality of the capacitor formed by the anode coating of the picture tube remains for a long time and the cathode is still emissive long after the receiver has been switched off due to the thermal inertia is.

It is known to provide the control electrode with a higher time constant than the cathode in the picture tube. When switching off of the receiver then the difference between the rake reduces ¹ S voltage at the cathode and the short time at the control electrode or the control electrode is positive relative to the cathode so that the charge of the high voltage source can flow before the deflection of the beam failed is. With this solution, however, there is often a flickering in the brightness, since one control electrode is held in the voltage and voltage fluctuations can only reach the other control electrode. A high time constant, for example on the Wehnelt cylinder, also increases the inertia of the brightness control in an inadmissible manner. It is also known to discharge the picture tube coating when the device is switched off by an additional contact. However, this measure fails if the device is put out of operation without operating the power switch. It is also known to take the bias voltage for a control electrode of the picture tube from a potentiometer, a voltage-dependent resistor being located between this potentiometer and the voltage source or ground. This resistance has the effect that a drop in the voltage at the control electrode is delayed, as a result of which the beam current is briefly increased. However, this circuit requires an additional voltage-dependent resistor. In addition, the effect on the control electrode depends on the respective position of the potentiometer. Since this potentiometer mostly serves as a brightness regulator, the protective circuit would work differently depending on the brightness set.

It has also been proposed to use the voltage divider for biasing the control electrode to switch between a positive and a negative voltage and the time constants for the decay these two voltages when switching off the receiver so differently measured that the Circuit arrangement

to protect the luminescent layer of the picture tube
in a television receiver

Applicant:

Telefunken

Patentverwertungsgesellschaft mb H.,
Ulm / Danube, Elisabethenstr. 3

Dipl.-Ing. Gerhard Ernemann and Alfred Pollak,

Hanover,
have been named as inventors

The voltage at the tap of the potentiometer increases briefly after switching off and the beam current this is also increased. However, this solution has the disadvantage that only a short voltage jump occurs at the control electrode, its duration is limited and which is not always sufficient to completely discharge the high voltage source.

The negative voltage jump that occurs when the receiver is switched off is also known to differentiate the operating voltage and in such a polarity of the cathode or a control electrode to feed the picture tube so that the beam current increases briefly and the high voltage source is discharged before the deflection of the beam is complete. But there is also this jump in tension is only brief, there is also no guarantee that the high-voltage source will be completely discharged. It is known in such a circuit, such a voltage pulse at the base of the brightness regulator to feed. However, this has the disadvantage that the voltage jump depends on the position of the brightness controller is more or less divided. In the case of contrast control circuits that correspond to the base of the Supplying a voltage to the brightness controller to adjust the brightness, difficulties also arise with the simultaneous supply of a voltage pulse for light spot suppression.

It is also known to adjust the bias voltage for the control electrodes of the picture tube by means of rectification of the deflection voltages so that the image

309 770/154

tube is locked as soon as the distraction is removed. desired way the charge of the high voltage

However, this solution has the disadvantage that exist through the source.

Blocking of the beam current the high-voltage. For a better understanding, the invention will be able to remain charged in the source "for days". In addition to a basic circuit diagram, this circuit is then no longer effective, 5 of some exemplary embodiments explained in more detail when the receiver and thus all operating voltages are switched off and only the high voltage Picture tube 1 is connected with its cathode 2 with the and the emissivity of the cathode of the picture anode 3 of a video output tube 4, the tube remain. Grid the rectified video signal is supplied It is also known, when switching off the receiver and its anode via a load resistor 5 catcher at the same time with an additional switch coupled to a positive operating voltage source + U _B power switch, a control element is connected. The control electrode 6 of the picture tube 1 trode the picture tube to one in the device beforehand is switched from a tap 7 of a voltage stored between the positive voltage with a capacitor to the operating voltage source + U _B and ground, which blocks the beam current. However, 15 th potentiometer 8 is required via a resistor 9 a separate switch, which must also be coupled with DC voltage to control the brightness of the off switch. In addition, picture tube fed. The high voltage source is not discharged between the resistor 9 and. the control electrode 6 is one according to the invention

It is also known to be connected to a control electrode of the DC voltage source 10, which is connected to Picture tube to put a fixed reverse voltage, which is the 20 its positive pole on the control electrode 6. The picture tube is also blocked by a high-voltage deflection circuit derived, opposite voltage source 11 is supplied with the high voltage. Above Voltage is compensated if the required Ab- a capacitor 12 of the control electrode 6 steering currents are present. In this circuit, blanking pulses 13 are also used to blank the however, the high voltage source also does not charge the electron beam during the line retrace. guided.

The invention avoids the disadvantages of the circuit in FIG. 2, the mode of operation of the circuit according to known circuits and specifically relates to a circuit. Up to time ti , the receiver is in the process of protecting the luminous layer of an establishment. The voltage U ₀ at the control electrode 6 at one electrode due to a variable voltage 30 is lower than the voltage U _K at the Kagesteuerten cathode ray tube, whose operating point method2 of the picture tube 1. At time ti , the anode voltage of the video output tube and receiver is switched off. The operation of a voltage + U _B , which is used to adjust the image brightness, and thus also the voltage at the cathode 2 taken from a tap of a brightness regulator and the voltage at tap 7 of the Pomen, which can be changed to a second 35 tentiometer 8 according to an exponential function together. While the voltage U _K at the cathode 2, which approaches the value zero when the receiver is switched off, the voltage U ₀ voltage difference between the two electrodes approaches that of the control electrode 6 approximately with the Change the same time picture tube in such a way that the beam current of the voltage E of the direct voltage source is increased so constant that the high voltage source remains before the 40 10, since the voltage E of this direct voltage source failure of the deflection of the electron beam initially remains. From Fig. 2 it can be seen that loading is. that with this arrangement the voltage difference

The invention consists in that between the cathode 2 and the control electrode 6

Tapping of the brightness regulator and the second control decreases very quickly, and that the voltage on the electrode of the picture tube a DC voltage source 45 control electrode 6 is greater than the voltage

is switched on, the positive pole of which is at the control of the cathode 2. This voltage difference U _0K is in

electrode is and its voltage is entered compared to Fig. 2 and approaches the value E.

the abiding time of the deflection so large time con This is achieved that the beam current after

constant and has such a large amplitude that the switching off of the receiver is greatly increased,

second control electrode after switching off the 50. This makes the high voltage source 11 very

Receiver is so positive that the high voltage is discharged quickly before the deflection of the

voltage source before the failure of the deflection ent receiver fails, so that a light spot that

loading is. usually after the distraction fails

Although it is known (German interpretation text appears on the screen, it no longer occurs

1055 699), ^{can be delayed} between the tap of the Helligkeitsreg- 55 and the screen of the picture tube against destruction

lers and a control electrode of the picture tube a fault is assured. The voltage E is about

Switch on DC voltage with a high time constant. 40 V. The tap 7 of the potentiometer 8 is thereby

However, this is directed in such a way that the electron beam is set in such a way that when the voltage E

after the operating voltage has ceased to exist, the desired beam current flows in the picture tube 1,

will. As a result, however, the invention based on 60 Since the DC voltage source 10 in a nearly

task, the high-voltage source is in the de-energized circuit, takes place when the receiver is in operation.

load, not be met. In addition, the catcher would not have to influence the brightness control.

The time constant of the voltage can still be great against- The risk of blinking phenomena of the brightness

over the already long cooling time of the cathode, there is also no mains voltage surges,

in order to prevent with certainty that the jet current 65 attempts have shown that it also suddenly occurs

short circuits of the positive operating voltage that occur again after the deflection fails

comes. The storage capacity would then be very large, in most cases no burn-in mark

will. In any case, however, it remains inexplicable. In practical cases it is not possible

a battery for the DC voltage source 10 in the To be installed in the device. It is therefore necessary to provide such a DC voltage source by charging a to form a relatively large capacitor.

In Fig. 3 a circuit example is shown, in which 5 by rectifying the positive horizontal flyback pulses a DC voltage is generated that charges a capacitor. In the figure are the same parts as in FIG. 1 are provided with the same reference numerals. The line deflection circuit 14 feeds once the deflection coils, not shown, and the high voltage source 11, it also supplies the. negative-going blanking pulses 13, also positive-going Line retrace pulses 15 which are fed to a diode 17 via a capacitor 16. By the diode 17, these pulses are rectified, so that on the capacitor 18 a positive DC voltage arises. The time constant created by capacitor 18 and the parallel resistor 19 is formed is large compared to the decay time of the distraction of the receiver, so that the The DC voltage across the capacitor 18 remains practically unchanged until the deflection has failed and the high voltage source 11 is completely discharged by the increased beam current. The on capacitor l8 DC voltage obtained, which is taken from the tap 7 of the potentiometer 8, for Brightness adjustment serving DC voltage is superimposed, is via a resistor 20, accordingly 1, the control electrode 6 is supplied. Since the control electrode 6 does not draw any current, lies the positive DC voltage source, formed by the capacitor 18, not in a DC circuit, as can be seen from FIG. 3. It is possible that when the receiver is switched off, a Current flows to the control electrode 6, which the DC voltage source in a galvanic circuit turns on. However, the capacitor 18 can easily be so large that the beam current in the Picture tube is maintained.

Fig. 4, in which the same switching elements as in Fig. 3 are again provided with the same reference numerals, shows an example of a circuit in which the one used to charge the DC voltage is used Capacitor 18, the negative line retrace pulses 13 are used, which are anyway for blanking of the electron beam on the control electrode 6, for example on the Wehnelt cylinder. Through this Circuitry, as can be seen by comparing FIGS. 3 and 4, is further reduced.

In the embodiment shown in FIG. 5, in which again the same switching elements as in Fig. 3 and 4 are provided with the same reference numerals, instead of a capacitive coupling the AC voltage to be rectified uses an inductive coupling. To that end is In series with the diode 17, a winding 21 is connected, which is an additional winding on the flyback transformer is.

6, in which the same switching elements as in FIGS. 3 to 5 are again provided with the same reference numerals shows a circuit example in which a diode 17, which is used to clean up the line blanking. This circuit also works with an additional winding on the flyback transformer for blanking, which is a sufficiently high voltage supplies to charge the capacitor to the required value, for example 40 volts. At the Point 22 of this circuit is the voltage set at tap 7 of potentiometer 8 to regulate the brightness of the picture tube; of this voltage is the direct voltage to be regarded as constant the capacitor 18 superimposed; these are in turn superimposed on the negatively directed ones Blanking pulses 13 generated by the diode 17, which is also used as a blanking diode, the resistor 23 and the capacitor 24 can be obtained.

In Fig. 7 a practically tested embodiment of the invention according to FIG. 4 is shown. Parallel to a part of the potentiometer 8 there is a photoresistor F, which is used for automatic adjustment the contrast depending on the brightness of the environment.

Claims (7)

PATENT CLAIMS: 1.Circuit arrangement for protecting the luminous layer of a cathode ray tube controlled by a variable voltage at one electrode, the operating point of which depends on the anode voltage of the video output tube and a variable bias voltage of a second control electrode, which is used to adjust the image brightness and is taken from a tap of a brightness regulator, whereby means are provided that change the voltage difference between the two electrodes of the picture tube when the receiver is switched off in such a way that the beam current is increased so that the high voltage source is discharged before the failure of the deflection of the electron beam, characterized in that between the tap (7) of the brightness controller (8) and the second control electrode (6) of the picture tube (1) a DC voltage source (10) is switched on, the positive pole of which is connected to the control electrode (6) and whose voltage (JE) has a time constant that is so large compared to the decay time of the deflection and a has such a large amplitude that the second control electrode (6) becomes so positive after switching off the receiver that the high-voltage source (11) is discharged before the deflection fails. 2. Circuit arrangement according to claim 1, characterized in that the direct voltage (E) is obtained by rectifying the line return pulses (15) obtained by the line deflection circuit (14). 3. Circuit arrangement according to claim 2, characterized in that as return pulses the negatively directed blanking pulses which are already on the control electrode (6) of the picture tube (1) (13), which are used to blank the electron beam during the line return, are used. 4. Circuit arrangement according to claim 2, characterized in that the return pulses (15) are taken from an additional winding (21) of the flyback transformer. 5. Circuit arrangement according to claim 4, characterized in that the additional winding (21) is connected in series with a diode (17) between the tap (7) of the brightness regulator (8) and the control electrode (6) of the picture tube (1). 6. Circuit arrangement according to claim 5, characterized in that in parallel with the series circuit the diode (17) and the additional winding (21) the parallel connection of a resistor (19) and a capacitor (18). 7. Circuit arrangement according to claim 6, characterized in that the through the capacitor (18) and the resistance (19) formed is large compared to the decay time the distraction. 1 sheet of drawings