DE756518C - Circuit arrangement for generating saegezahnfoermiger currents - Google Patents

Description

Circuit arrangements for generating sawtooth-shaped current curves are already known, where there is an inductive voltage feedback between the anode circuit of a controlled Tube and its grid circle is present, which consists of a parallel resonance circuit from a deflection coil and its own capacitance.

The invention relates to a modification of this circuit arrangement and to some further improvements of the same, which allow the current sawtooth curve to remain unchanged To be able to use a smaller tube in the deflection coil.

It is also known in a multiple oscillation generator which has two resistive capacitor elements has coupled discharge paths and in which both Discharge paths are housed in a single tube, parallel to the grid-cathode path turn on a rectifier of a discharge path .. this happens to that Purpose, a migration of the grid potential with respect to the cathode in the positive direction

prevent, because with such a potential shift a negative resistance in the Grid-cathode path could arise, which would cause the desired breakover oscillations of the multivibrator would make impossible.

Finally, it has also been suggested that the duration of the Anode current pulses through parallel connection of a rectifier to the grid-cathode path to keep constant, even if the anode current-grid voltage characteristic of the barrier tube due to tube wear or due to fluctuations in the operation of the blocking oscillator circuit serving direct voltage shifted.

Before the invention and its further improvements are explained with reference to Fig. 2 the mode of operation of the circuit assumed to be known, which is shown in Fig. 1 is to be set out.

The circuit according to Fig. 1 contains a three-pole tube 4, the anode circuit of which on its grid circle is fed back by means of the transformer 5, 6 and in which the grid circle contains a parallel resonance circuit, which consists of the deflection coil 9 and its intrinsic capacitance το. The capacitor 7, which is connected upstream of the deflection coil, only has the task of To prevent a direct current flow through the coil 9 and the capacitor 8 is used for smoothing the DC voltage tapped at potentiometer 3 and located in the control grid circuit of any harmonics. The anode DC voltage for the tube 4 is provided by a potentiometer 2 is removed, and the series connection of 2 and 3 is connected to the DC voltage source i.

The consideration of the mode of operation of the circuit according to Fig. 1 is best started at a point in time at which the anode-cathode section and the grid-cathode section of the tube 4 are de-energized and there is a high voltage across the capacitor 10, which the grid the tube 4 makes strongly negative with respect to its cathode, and in which in the deflection coil 9 no current flows. The windings 5 and 6 should also be de-energized at the point in time under consideration. If one follows the processes taking place on the basis of these initial conditions and finally arrives again at a state in which the same initial conditions prevail, one has passed through a complete period of processes taking place in the steady state. The capacitors 7 and 8 can be disregarded for the alternating current processes which are of primary interest here, since they can be assumed to be so large that the alternating currents do not form any appreciable voltage drops across them. The inductance of the secondary winding 6 can be assumed to be very large in the circuit according to FIG. The charge on the capacitor 10 will therefore try to balance each other via the deflection coil 9, which leads to a damped oscillation process. From these damped oscillations, calculated from the considered initial state, which may be denoted by t _{0, only about a quarter oscillation can develop undisturbed.} The current in the coil 9 thus assumes a maximum value which would be reached at the time t ₃ if the tube 4 were not present, and the voltage across the capacitor 10 would at the same time from its maximum value existing at the time f _{0 to the value zero} have subsided. Shortly before this point in time, however, when the reverse voltage limit of the grid in Fig. 2b is exceeded, anode current begins to flow, and due to the inductive voltage feedback, the grid voltage rises almost abruptly at time t ₂ , which is slightly before time t _a the grid voltage value of zero and beyond. In Fig. 2b, the grid voltage curve from time t _{2 is} indicated by a dotted line, which would apply in the event that the tube 4 were not present. Because of the surge of the grid voltage to positive values, grid current also sets in in the tube 4, and the deflection coil 9, in which a current flows, the magnitude of which can be seen in Fig. 2a, is via the resistance of the grid cathodes -Way short-circuited. The energy present in the capacitor 10 at the time t ₀ is therefore now present in the magnetic field of the deflection coil 9 and must balance itself out via the internal resistance of the grid-cathode path, which leads to an exponential decay of the deflection coil current. Since, however, as mentioned, a positive grid voltage arises at time t ₂ , both an anode current, which is shown in FIG

ι

is calculated from the anode current i _a to - i _a,

if with - the ratio of the number of turns

the transformer windings 5 and 6 is designated. The current in the winding 6 is directed from left to right in the time t ₂ to i _t and combines at the grid with the current flowing through the coil 9 during this time, which is directed from bottom to top. In the time t ₄ to t ₅ , the current in the winding 6 still has the same direction, while the deflection coil current has assumed the value zero at time t ₄ and then rises again in the opposite direction with unchanged steepness. However, because of the exponential decay of the deflection coil current already mentioned above, the differential quotient of this current changes a little, and

although it decreases, so that at time t ₅ the positive grid voltage has disappeared. As a result, the grid-cathode path is de-energized, and the current which flows in the deflection coil at time t ₅ can only be closed via the capacitor io, which means that a new oscillation process begins in the parallel resonance circuit 9, 10. The current flowing through coil 9 from top to bottom at time i _B charges the capacitor again in such a way that the capacitor voltage represents a negative bias voltage for the control grid of tube 4. At time t _e , the conditions that were assumed above at time t _{0 are already present again.}

This working method is essential for the invention

of the current sawtooth generator, it is important that at time i ₂ and shortly afterwards the cathode of the tube 4 must supply three times the amount of current and the control grid of this tube must carry twice the current than it flows in the deflection coil 9 during this time. This applies in the event that the transformation ratio of the transformer is ι: ι. If the transmission ratio, as is usually the case in practice, is still less than 1, ie the value ü is still less than 1, the ratios become even more unfavorable.
The known sawtooth generator described thus requires extremely large tubes with large cathodes and special grids with a high current carrying capacity.

According to the invention, the necessary in the known power sawtooth generator To be able to dimension the tube much smaller with otherwise constant conditions, So in order to be able to use a tube of the usual design, parallel to its grid-cathode path A rectifier is placed in the same direction of permeability.

An embodiment of the invention is illustrated in Fig. 3, in which of the Resistance 12 should initially be avoided. In this is the rectifier, which according to the Invention to the grid-cathode section of the tube 4 is parallel, denoted by 11, and the same reference numerals are used as in Fig. 1. The rectifier 11, which should receive a small internal resistance, takes over most of the current, which in the known circuit according to Fig. ι flows over the grid-cathode path. For even greater current relief of the control grid of the tube 4, one can according to a Improvement of the invention in the lead to the control grid insert a resistor 12, as can also be seen in Fig. 3. According to a further embodiment of the invention the control grid of the tube 4, as shown in Fig. 4, is only attached to a part of the winding 6 connected, while the rectifier 11 is on the entire winding 6. This amendment the circuit shown in Fig. 3 is advantageous because the voltage stress the insulation between control grid and cathode during the ramp-down times of the sawtooth current, in which at the deflection coil, As Fig. 2b shows, a very high voltage occurs, is reduced.

In the embodiment shown in Fig. 5, the deflection coil is also only on one Part of the secondary winding 6 of the transformer is connected, it then leaves a higher one Current load too. The rectifier 11 is also in this embodiment on the whole Secondary winding 6 and the control grid of the tube 4, also as in Fig. 4, only on one Part of the secondary winding.

According to the further invention, a resistor 13 in FIGS. 6 and 7, which is connected between the cathode of the rectifier and the cathode of the tube 4, is to be used to synchronize the current sawtooth generator. This resistor 13 can be used either in such a way that negative synchronizing pulses are applied to its left end, as shown in Fig. 6 and the cathode of the tube 4 is grounded, or in such a way that, as Fig. 7 shows , supplies positive sync pulses at its right end and grounds the codename of the rectifier tube 11. In the case of Fig. 6, the negative synchronization pulses are fed to the control grid of the tube 4 and thereby the grid current is interrupted so that, as explained for the time t _s on the basis of Fig. 2, the long edge of the sawtooth current is ended and the return is initiated . In the case of Fig. 7, the positive synchronizing pulses generate potential rises in the cathode of the tube 4 with respect to the control grid and thereby interrupt the grid current each time, so that a sawtooth return can begin.

A further improvement of the sawtooth current generator will now be described with reference to Figs. Figs. 2c and 2d show that in the time span t ₂ to i ₄ the anode current can have the value zero and in the time span t _i to t ₅ must be only slightly greater than the deflection coil current at every instant. According to a further embodiment of the invention, the grid voltage of the tube 4 can therefore be given the curve shown in Fig. 8, in which the grid voltage only allows an anode current to set in shortly before the middle of the long sawtooth flank, which is then approximately time-proportional until the end of the long Saw tooth flank increases. In the

The circuit shown in Fig. 9, in which this grid voltage curve occurs, differs differs from the circuit according to Fig. 7 in that the tube 4 is a screen grid tube. the The grid voltage, which increases in a sawtooth shape, is generated by the sawtooth generator itself generated, in the following way: With each interruption of the anode current of the Tube 4 and thus also the screen grid current is formed at the terminals of the secondary winding 15, whose associated primary winding 14 is in the screen grid circuit, a voltage surge from, which charges the capacitor 17 via the rectifier 16 as it is registered by the Plus and minus signs in Fig. 9 is indicated. Discharged during the sawtooth run-out the capacitor 17, the negative assignment of which faces the control grid of the tube 4 is, across the resistor i8, so that the grid potential as shown in Fig. 8 while of the sawtooth trace increases slowly. The resistor 13, which is connected in the same way as on Hand of Fig. 6 explained, is used for synchronization.

In all of the described embodiments, as shown in Fig. 9, the constant negative grid bias by means of an ÄC element 8, 19 with a sufficiently large Generate time constant instead of tapping it from a potentiometer.

Claims (6)

Patent claims. i. Circuit arrangement for generating sawtooth-shaped currents, in particular for Television purposes in which an inductive voltage feedback is effective between the anode circuit of a controllable one Tube and its grid circle, the one from a deflection coil and its own capacitance contains existing parallel resonance circuit, characterized in that parallel to the Grid-cathode section of the tube (4) of conventional design, a rectifier (11) in the same Direction of permeability (Fig. 3). 2. Circuit arrangement according to claim 1, characterized in that the control grid the tube (4) is preceded by a resistor (12) (Fig. 3). 3. Circuit arrangement according to claim 1 or 2, characterized in that of the full voltage available to control the tube (4) (voltage at 6) Part (left part of 6) is used for control (Fig. 4). 4. Circuit arrangement according to claim 1, 2 or 3, characterized in that the Deflection coil (9) only to a fraction of the feedback voltage, preferably to a tap on the secondary side (6) of the transformer providing the feedback (5, 6) is connected (Fig. 5). 5. Circuit arrangement according to claim 1 or one of the following, characterized in that that in the grid circle between the cathodes of the rectifier (11) and the Tube (4) has a resistor (13) on which the synchronization pulses are fed (Fig. 6 and 7). 6. Circuit arrangement according to claim 1 or one of the following, characterized in that that to reduce the anode load on the tube (4) a preferably derived from the sawtooth generator itself, saw-tooth voltage (Fig. 8) is also applied to the control grid of the tube (4) (Fig. 9). To differentiate the subject matter of the invention from the state of the art, the granting procedure the following publications have been considered: British Patent Nos. 455497, 456 640, 461325. For this purpose 2 sheets of drawings 5541 10.53