DE896829C - Process for the short-term suppression of the electron beam in electron beam tubes - Google Patents

Description

Method for the short-term suppression of the electron beam in Cathode ray tubes To temporarily move the electron beam into a cathode ray tube to suppress, are usually one of the electrodes of the cathode ray tube special impulses are supplied, which cause the beam suppression. This is how you lead for example the Wehnelt cylinder from Braunsehen tube negative or the cathode positive voltage impulses of the corresponding magnitude and duration, which are applied to the distraction of the electron beam serving coils are removed.

The aim of the invention is to suppress the beam by means of special measures to improve, in particular with regard to a constant duration of the beam suppression time. The invention is based on the knowledge that it is better instead of the previous one mostly for the purpose of beam suppression on the deflection coils or the like Pulses, which have an exponential course of the trailing edge, derived therefrom To use impulses of a different shape.

According to the invention, to suppress the electron beam in cathode ray tubes and the like. A method is used in which the preferably on the deflection inductances removed impulses causing the beam suppression trigger an oscillating circuit, on the pulse of constant duration with steep leading and trailing edges, preferably Half sine waves are removed. Only then do they turn into oppression of the electron beam and / or to block a downstream electron beam tube Amplifier used.

In the following, the invention is illustrated by means of the exemplary embodiments descriptive figures. Here, FIGS. 1, 3 and 4 serve for explanation of the inventive concept, FIGS. 2 and 5 show exemplary embodiments of the invention Switching arrangements.

Fig. I shows the time course of a on the deflection coils Braun's tube removed blanking pulse. The leading edge v of the pulse is steep, while the trailing edge r has an exponential, slowly decaying course having. Therefore, a correct sampling is possible during the end of the ramp-down time difficult. An oscillation circuit is triggered by the leading edge v of the pulse, whose period of oscillation z is practically twice as great as the intended period the beam suppression. The first half-wave of the oscillation excited in the oscillation circuit is intended according to the invention to suppress the electron beam; the second, The half-wave shown in dashed lines becomes parallel to the oscillation circuit through a switched discharge, seat range suppressed. As long as the one occurring in the oscillation circuit Voltage e is greater than the reverse voltage required for beam suppression esp, the electron beam is suppressed. With a suitable choice of reverse voltage esp is both at the time of the beginning of the beam blockage and the termination the beam blocking the course of the oscillation sufficiently flank part to a. timely: Use and timely termination of the beam blocking to ensure.

When applying the invention to television sets, it is advantageous according to FIG. 2 the oscillation circuit Z for suppressing the electron beam during the line retrace and the oscillation circuit B for suppressing the electron beam one after the other while the picture is reversed. The one to excite the oscillation circuit B pulses are here via the terminals i and 6 and the high resistance 2, the impulses used to excite the oscillation circuit Z via the terminals 3 and 6 and the high resistance 4 supplied. Parallel to the oscillation circuit Z lies a correspondingly biased by an RC element Diodenstnecke Dz, while to the Series connection of the two oscillating circuits a suitably biased diode DB is parallel. These two diodes make the positive and negative respectively sinusoidal half-waves of the associated oscillation circuit into a pulse-shaped one Reshaped stress curve. At the terminals 5 and 6, the finished mixture is the Line blanking pulses and picture blanking pulses and the cathode ray tube fed.

In Fig. 3 it is shown how by the action of the corresponding biased diodes. the negative, sinusoidal half-wave of the aforementioned oscillation circuit is transformed into a pulse-shaped voltage curve. The dash-dotted line Pulse a, to which the blanking pulse of FIG. 1 corresponds, triggers an oscillating circuit and generates in this damped vibrations according to curve b. While the first positive half-wave of the oscillation (fully drawn) through the diode not will be affected shortly after the start; the first: negative half-wave as soon as the diode has fallen below the negative bias ey, the diode is conductive. At Position of the hatched: sinusoidal impulse from area I. a rectangular impulse of small height but great duration with area II is created. The hatched areas I and II are identical to one another. By changing the bias ev one has it in hand, the end E of the square-wave pulse can be set arbitrarily within wide limits, so also like this; that it is with the following Impulse coincides.

In some cases, the potential jump occurring at E is disruptive, for example, if it occurs during the image transmission period, then the apparent brightness of the transferred image ice is suddenly changed. In these In cases it is advisable to choose the appropriate size of the diode series resistor to ensure that, B is the result of the transformation of one sine half-wave square pulse is not completed during the image transmission time. It is therefore expedient to the length of this square-wave pulse in such a way; Select, that it has not ended before the arrival of the next trigger pulse. Fng. 4 shows this case. The end E of the rectangular pulse coincides with the time the leading edge v of the incoming pulse s together or occurs in time a short distance afterwards.

5 shows another embodiment of the arrangement according to the invention, the two diodes Dz and DB being replaced by an amplifier tube 1 '. The pulses for suppressing the rewinding of the image are supplied via terminals i and 6 and the high resistance 2 of 5o kOhm, the pulses for suppressing the line rewind are supplied via terminals 3 and 6 and the high resistance 4 of 5oo kOhm. The oscillation circuit, which is matched to twice the duration of the line return, consists z. B. from the inductance Lz of 40 mHy and a capacitance Cz of 50 PF, while the double duration of the Bididirücklauf @ s. Alb tuned S, chwdngungsknei @ s from the inductance ZB of z. B. 3i Hy and a capacity CB of 20,000 pF. The oscillation of the first-mentioned oscillation circuit is deformed by the grid-cathode section of the tube Ir, whereby the necessary bias voltage is caused by the CR element (500o PF or 7 kOhm) in the grid feed line of the tube. The transformation of the oscillation of the other oscillation circuit takes place through the cathode-anode section of tube V. This discharge section is less effective than the grid-cathode section because of its greater internal resistance, and it is therefore advisable to suppress any that may still occur in the curve To switch on vibrations an attenuator consisting of the resistor 7 of 7 kOhm and the capacitor 8 of o, i pF. The finished mixture of blanking pulses is taken from terminals 5 and 6 and fed to the Braunsehen tube (not shown).

Claims (1)

PATENT CLAIMS: i. Method of suppressing the electron beam in cathode ray tubes and the like, characterized in that the beam suppression causing impulses to a resonant circuit = and that on that by this Impulse triggered oscillation circuit Impulse of constant duration with, #siteiler Vorderr- and trailing edge, preferably sine half waves, are removed, which only then to suppress the electron beam and / or to block the cathode ray tube downstream amplifier can be used. Order to carry out the procedure according to claim i, characterized by such a coordination of the resonant circuit, that its oscillation period is equal to or only slightly greater than twice the beam suppression period. 3. Arrangement for performing the method according to claim i, characterized in that da.ß a discharge path, preferably one, parallel to the oscillation circuit biased diode section or grid-cathode section of an amplifier tube. .4. Arrangement according to claim 3, characterized in that the impulses belong to the oscillating circuit are supplied via a high-ohm resistor, the resistance value of which is considerable is greater than the internal resistance of the discharge path. 5. Arrangement according to claim 3 and q. to suppress return in television broadcasts and the like, characterized in that, that two oscillating circuits are connected in series, one of which is about twice the duration of the line return time and the other about twice the duration the frame rewind time is matched, and that at the ends of this series connection the finished mixture of Auistas: timpulse removed and fed to the television tube will. 6. Arrangement according to claim 5, characterized gekennzeichn @ et that the two in series switched oscillating circuits a triode or multi-grid tube connected in parallel is such that the grid-cathode segment of this tube is one of the two oscillation circuits, preferably the oscillation circuit adjusted to double the return period, is connected in parallel. 7. Arrangement according to claim 6, characterized in that the oscillating circuit, which is not the grid-cathode section of the amplifier tube is parallel, in addition, a special attenuator is connected in parallel. B. Arrangement according to claim 7, wherein triggering pulses are periodically supplied, characterized in that the series resistor of the diode has such a size, that the square-wave pulse created by the transformation of a sine half-wave has not ended before the next trigger pulse arrives.