DE1174826B - Circuit arrangement for protecting the luminous layer of the picture tube in a television receiver - Google Patents

Description

Circuit arrangement for protecting the luminous layer of the picture tube in a television receiver With television receivers, when the device is switched off the risk that the beam current of the picture tube persists longer than the deflection and burn the resulting light spot on the screen of the picture tube can. 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 due to thermal inertia long after the receiver has been switched off is emissive. There are many circuits to suppress the luminous point have been suggested, but either not effective enough or an undesirable one Have an influence on the image reproduction. In addition, the effort is usually relatively large.

It is known, in the picture tube, the control electrode circuit with a to provide a higher time constant than that of the cathode. When switching off the receiver the difference between the voltage at the cathode and the at the control electrode briefly, or the control electrode becomes positive in relation to it the cathode, so that the charge of the high voltage source can flow away before the Deflection of the beam has failed. However, this solution often arises a flickering in the brightness, because one of the control electrodes held in the voltage and voltage fluctuations can only reach the other control electrode. With a high time constant, for example on the Wehnelt cylinder, the inertia of the brightness control increases impermissibly. It is also known when the device is switched off by an additional contact, the picture tube coating to unload. However, this measure fails if the device is operated without operating the Power switch is put out of operation. It is also known the preload for a control electrode of the picture tube to be removed from a potentiometer, with between this potentiometer and the voltage source or ground a voltage-dependent Resistance lies. This resistance causes a drop in the voltage across the Control electrode is delayed, whereby 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 dependent. Since this potentiometer is mostly used as a brightness regulator is used, the protective circuit would be different depending on the set brightness work.

It has also been proposed to use the voltage divider for the bias to switch the control electrode between a positive and a negative voltage and the time constants for the decay of these two voltages when switching off of the receiver to be dimensioned differently so that the voltage at the tap of the. Potentiometer increased briefly after switching off and the beam current thereby is also increased. However, this solution has the disadvantage that only a short voltage jump occurs at the control electrode, the duration of which is limited and which is not always sufficient to discharge the high voltage source completely.

It is also known what happens when the receiver is switched off to differentiate negative voltage jump of the operating voltage and in such a To feed polarity of the cathode or a control electrode of the picture tube that the Beam current is briefly greatly increased and the high voltage source is discharged before the deflection of the beam is finished. It is also with such a circuit known to feed such a voltage pulse to the base of the brightness regulator. In contrast control circuits, the base point of the brightness regulator is a voltage for brightness adjustment, however, difficulties arise with the simultaneous supply of a voltage pulse for suppression of luminous spots.

It is also known the bias for the control electrodes of the picture tube by rectifying the deflection voltages so that the The picture tube is locked as soon as the distraction ceases. But this solution has the Disadvantage that by blocking the beam current the high voltage source "for days" can stay charged. In addition, this circuit is no longer effective when the receiver and thus all operating voltages are switched off and only the High voltage and the emissivity of the cathode of the picture tube remain.

It is also known to switch off the receiver simultaneously with an additional switch coupled to the mains switch, a control electrode the picture tube to one previously stored in the device with a capacitor To apply voltage that blocks the beam current. However, this is a separate Switch required, which must also be coupled to the off switch. aside from that the high voltage source is not discharged.

It is also known to a control electrode of the picture tube to put fixed blocking voltage, which blocks the beam current and only then through a the opposite voltage derived from the deflection circuit is compensated, when the required deflection currents are present. In this circuit, however, also do not discharge the high voltage source.

It is also a circuit arrangement with one on one electrode proposed by a variable voltage controlled cathode ray tube been between the tap of the brightness regulator and the second control electrode the picture tube a DC voltage source is switched on, the positive pole of which is on the control electrode and its voltage is compared to the decay time of the Deflection has such a large time constant and amplitude that the second Control electrode is so positive after switching off the receiver that the The high voltage source is discharged before the deflection fails.

It is also known between the tap of the brightness control and a control electrode of the picture tube to switch on a DC voltage with a high time constant. However, this is so directed that the electron beam after the operating voltage has ceased to exist is blocked.

It is also known that the screen grid is grounded via a capacitor to connect the picture tube to an operating voltage source via a switch, which is coupled to the power switch. It is closed during operation and opened when the device is switched off, so that then only the capacitor voltage on the screen grid is effective. Since after opening the switch for the capacitor no or hardly any there is a discharge path, this capacitor maintains its voltage for a relative long time, so that discharge of the high voltage source is achieved with certainty will. However, this circuit has the disadvantage that the protective circuit is ineffective is when the device is switched off by pulling the power plug or when the Mains voltage fails. According to the invention, the switch is on the reduction the operating voltage automatically reacting switch. In one embodiment According to the invention, the switch consists of a diode whose cathode is connected to the screen grid and whose anode is connected to the operating voltage, so that in the event of a drop the operating voltage, generally the booster voltage, the diode the operating voltage separates from the screen grid. Another advantageous solution results from use a switch made of a pair of contacts, which is melted into a gas-filled glass tube is. With such a switch, the contacts are conductively connected to one another, as soon as the glass tube is in the area of a magnetic field. Such a magnetic field can e.g. B. the stray field of the filter or the vertical output transformer be.

To explain the invention in more detail, several exemplary embodiments are provided described on the basis of the drawings.

In Fig. 1 shows the picture tube 1 of a television receiver, the cathode of which video signals 2 are supplied. The screen grid of the picture tube is on Via a small capacitor 3 to ground, the capacitor 3 being dimensioned as large is that in normal operation through him and connected resistor components such a time constant is formed that there is no delayed influence in the event of mains voltage fluctuations can take effect. The operating voltage for the screen grid is derived from the booster voltage which is available in the line deflection circuit of the television receiver. This voltage is generated from the resistors 4 by an ohmic voltage divider and 5 divided down to the required value. From the same voltage divider, z. B. from a tap 6 of the resistor 5 is the operating voltage for the focusing electrode the picture tube tapped. The high voltage for the picture tube is generated by stepping up and rectification of those occurring in the flyback transformer 7 during flyback Return pulses generated, the capacity of the through the picture tube wall and the corresponding assignments given capacitor as a smoothing capacitor for the generated high voltage is used. This capacitor has such a quality to ensure that the high voltage persists for days even after the receiver has been switched off can, if the relevant cargo cannot be discharged by any means would. According to the invention, the high voltage source becomes automatic by using one responsive switch 8 discharged when the operating voltage for the screen grid drops the picture tube separates the operating voltage source from the screen grid, so that then alone the voltage of the capacitor 3 on the screen grid remains effective. This voltage corresponds to the operating voltage existing at the time of opening of the switch 8, the lack a discharge path for the capacitor 3 remains there for a relatively long time. In this way, the high voltage source is discharged via the beam current, before the distraction itself subsides.

The mode of operation of the circuit described so far is described below are explained in more detail.

F i g. 2 shows the course of the high voltage Uli " in the first seconds after switching off the receiver, curve a corresponding to a receiver without special means for beam current suppression, curve b, however, to a receiver whose control grid after switching off, for example, by an additional one with the Finally, curve c shows the course of the high voltage after switching off in a circuit according to FIG. 1. It is easy to see that the drop in curve a occurs very slowly so that even after the deflection process has subsided, ie after a good 1 second, there is still a high voltage which causes a light spot on the screen in the long-emitting cathodes used today some tube types can still cause a light spot, because there the high voltage is reduced very quickly to a relatively low value tzt, but there are some types of tubes that can produce a light spot even at relatively low high voltages. In the circuit corresponding to curve b, however, the low high voltage remains for a relatively long time. As curve c shows, when the circuit according to the invention is used, the high voltage has dropped to practically zero after just 1 second. Thus, when using the invention, there is no need to worry about an undesired light spot even if the picture tube is dimensioned such that a light spot is generated even at low high voltages.

It has now been shown that even after a discharge of the high voltage source, z. B. by applying a positive voltage to the control grid of the picture tube, after switching off the high voltage source a new one after some time High voltage is formed, the so-called residual voltage. This tension can itself with previous use of circuits for red dot suppression approx. 15 seconds reach a value of 2 kV after switching off and then increase to 5 kV. Since the cathodes of the picture tube most commonly used today are practically 1 minute behind emit after switching off, such residual voltages still generate a light spot, when all other electrode voltages are already at ground potential.

In Fig. 3 is the curve of the residual voltages for known circuits with luminous dot suppression (curve a + b) and for a circuit according to the invention (Curve c). With regard to these voltages, too, it can be seen that the light spot suppression according to the circuit according to the invention is already more effective than with the known Circuits.

This does not only affect the level of the residual stress from which in the known circuits to about 5 kV, in the case of the invention Circuit only increases to about 1 kV. There is a much greater benefit here still in the fact that in the known circuits the residual voltage is already after 10 seconds exceeds the value of 1 kV, while in the case of the invention Switching noticeable only after 90 seconds and the value only after 2 minutes of 500 V. As noted above, the cathode's emission duration is the picture tubes used today usually only take a good 60 seconds after being switched off, so that a light spot due to the residual voltage in the inventive Circuit is definitely avoided.

In Fig. 4 shows the profile of the screen grid voltages in the known circuits and in the circuit according to the invention. The curve a + b, which corresponds to the known circuits, shows that in the known circuits the screen grid voltage decays very quickly, while in the circuit according to the invention (curve c) it is about 6 times the value after 1 second compared to the known circuits , Has. This course of the screen grid voltage also contributes to the good effect of the circuit according to the invention, because with low voltages on the screen grid only a relatively small beam current can flow in the picture tube, so that the discharge of the high voltage source cannot be effective due to rapidly falling screen grid voltages. It is true that the screen grid voltage could be maintained by means of a relatively large screen grid capacitor, but this would, among other things, introduce a sluggishness into the control mechanism of the image signals and thus cause so-called blinking.

According to the invention are to operate the in F i g. 1 shown Provide switch 8 automatically acting means that take effect when the operating voltages drop.

In Fig. 5 shows such a circuit in which instead of the Switch 8 a diode 9 is provided, the cathode of which with the screen grid and its anode with the operating voltage source or with the tap of the voltage divider 4, 5 is connected. In the normal operating state, the operating voltage is applied to the screen grid, the capacitor 3 being charged to this voltage. The capacitor 3 has a relatively small capacity, e.g. B. 3.3 nF, and is therefore for the operating state of the device optimally dimensioned. As soon as the voltage at the anode of diode 9 drops, blocks the diode 9, and the capacitor 3 remains with the intended voltage alone effective on the screen grid and thus keeps the picture tube in a for a large beam current favorable working point.

Another embodiment of the invention is shown in FIG. 6 shown. In this circuit, the switch 8 is used as a contact of a relay 10, the corresponds to the standard circuit diagram in the illustration shown. In practice you will this relay expediently train as a gas-filled glass tube into which the two Contacts are melted down. This switching element should be dimensioned so that between There is a conductive connection between the two contacts as long as the glass tube is in place is penetrated by a magnetic field. It is advantageous to use the glass tube in the stray field of the receiver's filter choke or one of the output transformers to arrange. Especially in those cases where the screen grid voltage for the picture tube is derived from the booster voltage, that has the advantage that with a Short circuit or an interruption in the deflection part, in which the deflection is jerky collapses, the screen grid voltage due to the small capacitor 3 very breaks down quickly, while normal shutdown does not.

Claims (6)

Claims: 1. Circuit arrangement for protecting the luminous layer a picture tube in which the screen grid is grounded via a relatively small capacitor the picture tube is connected to an operating voltage source via a switch, which is closed during normal operation and when the operating voltage is reduced is opened, so that then on the screen grid with reduced operating voltage alone the capacitor voltage is effective, that the switch (8, 9) on the reduction of the operating voltage automatically responsive switch is. 2. Circuit arrangement according to claim 1, characterized in that the switch is a diode (9) whose cathode is connected to the screen grid of the picture tube and whose anode is connected to the operating voltage (F i g. 5). 3. Circuit arrangement according to claim 1, characterized in that the switch consists of the contacts of a relay (10) (F i g. 6). 4. Circuit arrangement according to claim 3, characterized in that the switch consists of a contact pair fused into a gas-filled glass tube, the contacts being conductively connected to one another when the glass tube is penetrated by a magnetic field (F i g. 6). 5. Circuit arrangement according to claim 4, characterized characterized in that the glass tube in the stray field of the filter choke or an output transformer of the receiver is arranged. 6. Circuit arrangement according to claim 1, characterized in that that the operating voltage is the booster voltage reduced by means of a voltage divider is. 1r. References considered: U.S. Patent No. 2,638,562.