DE1509694U - - Google Patents

Description

Klppgr & t for Brmnsohw stirring, inebwaondwrw door Yornsehawooke. for ywynahzwwokw. There are circuits for a proportional dis- steer steering of cathode rays known, in which a cord e charged via a resistor or a tube and is discharged through a discharge tube. The parallel im Condenser discharge tubes can be a tube with gas filling or a vacuum tube. In the first case. comes the discharge of the capacitor of self-states when the ignition voltage at the capacitor has been reached. In contrast. in addition, when using an electron tube as an ent- loading tubes a discharge only when the tube is for the discharge by a pulse to be applied to the grid is opened. The tubes are usually like this negatively biased so that an anode current no longer flows, At the moment when the grid of the electron tube enters positive pulse is supplied, the condensate discharges gate according to »indication of the height and duration of the impulse. At the in Television, this impulse is referred to as a synchronizing impulse. net. Such circuits with high vacuum tubes as Chargers have the advantage over the gaage-filled tubes that the reverse tipping is used with greaterb accuracy and So start getting more and more into the world of television respectively. However, there is still a liability to these attitudes participate in, as set out below did. When the synohroni No impulses for some reason, ao remains the tube is always blocked, ie the cathode ray remains stand in the same place of the solemn. Is that the beam now just controlled to "bright", the screen is on burn this place for a very short time and one see welsen the brown fleok, which is unsanitary, and the Fernild disturbs. In the event that the synchronization impulses fail, occurs z. B. is used when switching off the transmitter first the modulation voltage is switched off and then the carrier wave runs through for some time until it is kept at full amplitude, but this could be remedied by a measure on the transmitter side. If, however, disturbances occur with the amplitude of the far threshold, then one is powerless against it. Such interference thresholds cover the synchronization pulses of the television sander and thus control the cathode ray continuously to "bright" without actuating the tilting direction.

This disadvantage of the previous circuit is avoided by the invention. The invention proposes connecting a glow tube in parallel to the vacuum tube serving as the discharge element, the ignition voltage of which is above the peak voltage of the breakover capacitor. Stay one now Synchronization pulse off, -'a shows the voltage, condensate Keep the gate on until the ignition voltage of the glow stray smoke is reached. At this moment the capacitor discharges to the point of release of the glow voltage.

This process is repeated until synchronization pulses are restored occur on the grid of the electron tube. Of course is the subject of the invention not limited to the use of a vacuum tube as a discharge organ, because too In the case of gas-filled discharge tubes, it can happen that the capacitor does not will tip over if the discharge tube is defective or its filament is not yet has reached the correct annealing temperature.

An example embodiment of the inventive concept is shown in FIGS. The circuit diagram will first be explained with reference to Fig. 1. In this circuit diagram, 1 means the breakover capacitor, but a resistor 2 is charged. The electron tube 3 is normally used as the discharge element, the grid sizes 4 and 5 of which are supplied with the synchronization pulses. The glow lamp 6 is still missing in this electron tube connected in parallel with the protective resistor 9. The tilting vibrations are picked up via terminals 7 and 8 and fed either directly or via amplifiers to the deflection plates of the Braunsohen pipe. Assume first that the synchronization works normally, then increases on Capacitor 1 the voltage during the time 2 1 am to Point 10 and then falls back to the initial value during time T2. (Fig. 2). Then, for whatever reason, the synchronization may stop. The capacitor voltage will then rise beyond point 10 to point 11. At this moment the glow lamp ignites and the capacitor voltage drops to the looseness voltage (12). This is then repeated between points 11 and 12 Play as long as the Synohrunisierimpulae fail. First when the synchronization pulses return, the lamp goes out again completely and the electron tubes 3 come into operation again.

In addition, the Gllmmstreoke according to the invention provides protection against overvoltage on the electron tube and on the breakover and coupling capacitor. You can therefore go to much higher charging voltages than ea was previously the case. It is known that only a small fraction of about 10% of the charging voltage can be used for the breakover voltage when charging via a resistor, because the capacitor voltage rises sufficiently linearly only in the lower range of the charging process. To give an example, you can now use around 5000 V as the charging voltage, so that the peak value of the breakover voltage is around 500 V and can be used for deflecting the cathode ray without amplification. Without the glow tube, the discharge tube would have to be dimensioned for a voltage of 5000 V in such a circuit, while when using the glow tube according to the invention the discharge tube never comes to this voltage. The same applies to the charging and coupling capacitor. These too now only need for the round voltage of the glow tube to be dimensioned.

The chimney tube required in the invention does not represent a significant one Increased circuit complexity, because it is a two-electrode tube with cold cathode. Such pipes are extremely simple and cheap.

Claims (1)

Protection claims! ---------, 1. Kippgerat for Braunsohe tubes, especially for television purposes, in which a capacitor is charged with constant current and discharged via a discharge tube, characterized in that a glow tube is connected in parallel with the discharge tube, the ignition voltage of which is above the peak voltage of the capacitor that occurs during normal operation . 2. Tilting device according to claim 1, characterized in that that a controlled vacuum tube serves as the discharge tube. 3. Kippgerat according to claim 1 and 2, connected by using charging voltages above the Durohsole resistance of the electron tubes and the charging and coupling capacitor. 4. Kippgerat according to claim l to 3, characterized through the use of charging voltages that are taken from the anode voltage source of the Braun tube. 5. Tilting device for Braun tubes, especially for television purposes, in which a capacitor is charged with constant current and via a discharge tube is discharged as shown and described.