DE716371C - Method for building up the images in television cathode ray tubes, in which the tilting vibrations are generated by charging and discharging a capacitor using glow lamps - Google Patents

Description

Method for building up the images in television cathode ray tubes which the breakdown oscillations by charging and discharging a capacitor. use generated by glow lamps -. When using glow lamps, in particular gas-filled incandescent glow lamps, as discharge tubes in the well-known flip-flop circuits the first part of the discharge runs so fast that the corresponding part the return line of the image change-over tilting process running across the image field becomes visible. In contrast, the discharge goes on the last part of the discharge curve just before 'the beginning of the deletion relatively - slowly' ahead of you.- This part the return line is therefore visible on the screen of the Braun tube. The course of the return line is shown in Fig. Z. The chamfering of the picture surface takes place here in the direction from bottom to top, the backlash line begins, therefore at the top of the picture: the upper part of the return line, the one with a sharp kink starts at z, is invisible up to point 2. The lower part of the return line on the other hand it thickened "found is disturbing in the picture. The invention gives- a procedure - which overcomes this disadvantage. - 'To generate - if possible Return lines free = images - by means of tilting vibrations -stetie-rter- cathode ray tubes in televisions, in which the tilting oscillation is not caused by charging and discharging a capacitor = using glow lamps, preferably «grid-controlled with gas. from Lower pressure filled incandescent glow lamps are generated - is according to the invention the charging capacitor does not reach the flat part of the discharge characteristic, but only discharged to a potential at which the return line is just about runs fast enough and for the eye of the vain observer not yet a bldinbalt leaves a disturbing impression. For this purpose, the discharge circuit of the breakdown capacitor with each discharge of the capacitor in the point of use of the strongly visible part the return line or in the vicinity of this point in time a voltage surge. from one the capacitor voltage is fed to the opposite voltage, which is at least just as large, but appropriately larger, than the one present at that moment Capacitor voltage. This leaves: the straight-on the terminals of the capacitor prevailing tension exist, so that the return line -at the starting point of the .The counter voltage breaks off and consequently completely disappears from the picture. This makes the one in Fig. I below the horizontal one passing through the point = Parts of the grid area that are straight and bordered by dashed lines are no longer drawn, if a1: o is dropped. Here, of course, the individual switching elements are earthed from the start dimensioned so that the bright part of the return line is outside the screen would.

An arrangement with which this method can be carried out is shown schematically is shown in Fig. 3 is an incandescent glow lamp, which is expediently over a grid is operated with a suitable constant, negative bias voltage; 5 is a capacitor, which is charged in a known manner via the resistor ¢ from the battery 6. A power amplifier with a wattless input is connected to the capacitor 5. In the anode line of the amplifier 7 there is a resistor, for example 8 and the capacitor g existing delay element and the primary winding a high frequency step-down transformer io. The appropriate with very low high frequency impedance executed secondary winding of this transformer, which is also carried out by a small Capacitor i i can be bridged, lies in the discharge circuit. The mode of action the arrangement is as follows: While the charging of the breakover capacitor 5 the Discharge tube 3 through its control grid for all anode voltages that occur is blocked and therefore the high-frequency transformer io is ineffective when discharging in the node circuit of the connected amplifier tube 7, a high frequency Pulse generated, which is transmitted well through the selective transformer. In the delay element 8 # 9, a delay of such a size is set that only after one of the duration of the invisible branch of the return line 1,: 2 in Fig. I corresponding time the high-frequency shock wave to the primary winding of the Transformer io arrives, in the secondary winding of which generates a voltage surge, whose size is at least the same, but is expediently larger than the one currently available Capacitor residual voltage; the phase of the voltage surge must be at the first moment opposite to the capacitor voltage. With a suitable dimensioning of this counter-voltage it is easy to achieve that the duration of the de-energized state on the Anode of the glow tube for complete deionization of the glow path: sufficient. The later voltage curve in the transformer secondary winding is then irrelevant: any decay processes that occur are therefore. harmless, there. the En-1.7 charge tube blocked again for all anode voltages as a result of the csitter effect coming into force is.

Another embodiment of the inventive concept is shown in Fig.3 shown schematically. The counter voltage that blocks the discharge is not through feedback from the discharge process itself, but from the synchronization voltage empty for the breakdown oscillation. This tension, which z. B. also from a distance can be transmitted, is indicated in Fig. 3 by the generator 12. Legs television this voltage is necessary for operation anyway and is used by the television receiver delivered to rlie toggle switch. The voltage 12 is initially via a phase shifter 13 led to their correct timing in the discharge process of the capacitor manufactures. It then arrives at a suitable amplifier 1.5. This amplifier must be able to connect to your AC resistance connected to the discharge circuit 16, e.g. B. a small coil to produce a voltage of low level, which Sufficient to the anode voltage at eler Glininientladungsröhre 3 for a sufficient Making time equal to zero or negative. The curve progression after this time is irrelevant. Behind the amplifier 15 there is expediently a highly conductive one for high frequencies Switching element 17 connected upstream, the conductance of which for the useful frequency of the breakover oscillation is extremely small.

In the method according to the invention. So becomes the breakover capacitor in each case not, except for zero, but only as far as point a of the return line in Fig. i corresponding potential discharged. The image shortening caused by this Loss of voltage is caused by increasing the working voltage without Compensate for difficulty.

Claims (6)

Pr1TF, NT CLAIMS: i. Method of building the images in television cathode ray tubes, at dent the tilting vibrations for deflecting the cathode ray by charging and discharging a capacitor using glow lamps, characterized in that that the charging capacitor does not extend into the flat part of the discharge characteristic, it is only discharged to a potential where the return line is straight is still fast enough and the image content is still not visible to the observer's eye leaves a disturbing impression. 2. The method according to claim i, characterized in that ciaß your discharge circle of the Breakdown capacitor in each case at the point in time in which the disturbing and visible to the eye part of the return line begins or near this point in time a voltage surge from one of the capacitor voltages opposite voltage is supplied, which its absolute value according to at least just as large, but expediently greater than the capacitor voltage. 3. Procedure according to claim 2, characterized in that the counter-voltage is derived from the breakover voltage itself is derived. Arrangement for carrying out the method according to the claims 2 and 3, characterized in that a high frequency step-down transformer is provided whose primary winding in the anode lead is one of the glow lamp voltage controlled power amplifier and its expedient with very low high-frequency impedance executed secondary winding is in the anode lead of the glow lamp. ;. arrangement according to claim 4, characterized in that between the anode of the amplifier and a delay element is arranged in the primary winding of the transformer. 6. The method according to claim 2, characterized in that the counter voltage from the synchronization voltage for the breakover oscillations is derived. . arrangement for carrying out the method according to claims 2 and 6, characterized by a phase shifter through which the counter voltage derived from the synchronization voltage is directed. B. Arrangement according to claims 6 and i, characterized in that that the phase shifter is followed by an amplifier and, expediently, a high-frequency filter are.