DE819567C - Electrical circuit arrangement with vibration generators - Google Patents

Description

The invention relates to an electrical circuit arrangement with vibration generators.

In more recent known embodiments, included electrical vibration generators or multiple breakers first and second electron discharge tubes, each of which is a cathode Has a control grid and an anode, the tubes being coupled together for operation alternately guide and generate tilting vibrations,

ίο where each period has two parts. The coupling is through a first coupling member between the anode of the first tube and the control grid of the second tube, and effected by a second coupling member between the cathodes of said tubes, where the length of the period parts by the time constants of the circles belonging to the tubes is determined. In such an embodiment, the tubes are alternately conductive and non-conductive, and although the first tube may be controlled by the application of suitable control pulses, so will it switch from one state to the other if a control pulse does not occur. The ones described here Circles already have many advantages over older versions of vibration generators. However, for certain purposes it may be desirable to use a vibration generator at to which the change from one state to the other is only advertised when a control pulse is applied. It is the purpose of the present invention to provide a circuit arrangement in which the aforesaid Goal is achieved.

According to the present invention there is provided an electrical circuit arrangement of this type, in which the length of one of the period

divide determined by the time constant of a circuit containing a capacitance in the first coupling element and the length of the other part of the period is regulated independently of the time constant mentioned is that one of said Peiiodenteile remains stable, and furthermore the second coupling member an impedance or impedances in such an arrangement and in the cathode circuits of said tubes of such size that when in operation there is no current

ίο flow between cathode and control grid of each tube can.

In a further embodiment of the present invention, said second coupling member contains said tubes in the cathode circuits Resistive impedances arranged and of such magnitude that in operation essentially no current can flow between the cathode and control grid of each tube, the length of one of the called period parts is determined by the time constant of a circle, which is the resistance impedance in the cathode circuit contains one of the tubes and the capacitance between the cathodes while the duration of the other part of the period independent of the time constant of the mentioned capacity and the

as resistance impedance in the cathode circuit of the other Tube is determined so that the latter part of the period becomes stable.

According to this invention, instead of having two unstable states, the generator has one stable and one unstable state, so that when the generator has been brought from stable to unstable state and returns to the stable state, a change from stable to unstable state can only occur can when a control pulse is supplied.

The invention will now be described as an example with reference to the drawings.

Fig. Ι represents an embodiment according to the invention the electrical circuit arrangement;

Fig. 2 shows voltage curves for various electrodes of the tubes contained in Fig. 1;

Fig. 3 illustrates another embodiment of the electrical circuit arrangement according to the invention; j Fig. 4 shows voltage curves for various electrodes of the tubes contained in Fig. 3; '

FIG. 5 shows a variant of that shown in FIG electrical circuit arrangement;

FIG. 6 shows voltage curves for various electrodes of the tubes contained in FIG.

In the circuit of FIG. 1, a unilaterally conductive device in the form of a diode 3 is connected between the cathodes of the tubes 1 and 2 and the anode of the diode 3 is connected to the cathode of the tube 1, while the cathode of the diode is connected to the cathode of the tube 2 lies. Here, the bias voltages are chosen so that the diode 3 becomes conductive when the tube 1 is conductive. If the tube 1 is rendered non-conductive by the application of a negative triggering pulse, the diode 3 also becomes non-conductive, while the tube 2 remains conductive, as can be seen from the curves of Fig. 2 of the drawings, until the tube 1 becomes conductive again. At this stage the cathode potential of the tube 2 begins to fall and falls until the tube 2 becomes conductive. In the present invention, however, the presence of the diode 3 stops the lowering of the cathode potential of the tube 2 when this potential has fallen so far that the diode 3 conducts, thereby preventing the tube 2 from being conductive. In this way, the tube 1 remains conductive and the circuit remains in a stable state until the tube 1 is made non-conductive again by applying a triggering pulse. The duration of those operating periods during which the tube 1 is conductive is therefore not determined by the time constants of R _t and C. If desired, the tubes 1 and / or 2 and the diode 3 can be arranged in a common envelope.

3 of the drawings shows an electrical circuit arrangement according to another embodiment of the invention. In this case, the bias voltages applied to the control grids of tubes 1 and 2 are chosen so that tube 2 is normally non-conductive and tube 1 is conductive, the latter tube remaining conductive until the beginning of the period after the application of a triggering pulse that controls the control grid of tube 1 is sufficiently negative to make tube 1 non-conductive. If desired, the grid leakage resistance R _{1 of} the tube 1 to which the trigger pulses are applied can be bridged by a one-sided conductive device shown in Fig. 3 as diode 4, with the result that the tube 1 is non-conductive when a trigger pulse of positive polarity is applied is made. 4 shows the voltage curve of the control grids of tubes 1 and 2 for the case that the diode 4 is connected in the manner shown and positive triggering pulses of the form shown in the figure are fed to the control grid of the tube 1 through the input capacitor shown.

If the diode 4 is omitted, the trigger pulses instead of the positive ones shown in FIG Polarity have negative polarity.

The arrangement shown in Fig. 3 can also be used as a frequency divider for fairly low division ratios, such as B. 2: 1, can be used.

If desired, the resistor R _{5 can be} replaced by a tube which is conductive at rest, in which case the circuit is controlled so that the tube 1 is rendered non-conductive by applying a negative trigger to the control grid of the resistor R ₅ replacing Creates a tube, whereby the current in it is interrupted for a moment.

Fig. 5 of the drawing shows a circuit in which the stability of the unstable part of the operating period is improved by applying a bias voltage to the control grid of the tube 2 via a one-sided conductive device shown as a diode 5. The lower end of the grid lead R ₂ is at a point of lower potential than the anode of the diode. With this arrangement it can be achieved that the diode 5 conducts after the tube 2 has come into the non-conductive state in order _{to discharge the capacitor C 1} as quickly as possible, so that the circuit is again more quickly receptive to triggering pulses than it would otherwise would be the case. Fig. 6 shows the grid voltage curve of the tubes 1 and 2 of Fig. 5, wor-

from one sees that by the action of the diode 5 the duration of the negative grid voltage surge Tube 2, if this tube is made non-conductive, is less than the duration of that shown in FIG Impact, so that the tube 2 by the next trigger pulse, if desired, very shortly after the Return to the stable state can be made conductive.

In the circuits shown in Figs. 1, 3 and 5, the output pulses can either come from the anode the tube 1 or from the anode of the tube 2 can be removed. In the one shown in the drawing Example in which the anode of tube 1 is coupled to the grid of tube 2, the anode of tube 2 be connected in series with any impedance, especially if the tube is a tetrode or Pentode is. In Fig. 5 of the drawings, the tubes ι and 2 are shown as pentodes. If it is in this If it is desired to generate pulses that are of shorter duration than the unstable period of the generators a short-circuited delay element can be inserted in the anode circuit of the tube 2, as at 6 in FIG. 5 indicated, are incorporated, whereby the anode potential of the tube 2 changes as it is in FIG. 6 is shown.

Claims (4)

Patent claims: ■ 1. An electrical circuit arrangement with oscillation generators, which contains a first and a second electron discharge tube, each of which has a cathode, a control grid and an anode, and wherein said tubes are coupled to one another in such a way that they conduct alternately during operation and generate relaxation oscillations, each period consisting of two parts, and further coupling being effected by a first coupling member between the anode of the first tube and the control grid of the second tube, and by a second coupling member between the cathodes of said tubes, characterized in that the duration of a said period parts determined by the time constant of a circuit with capacitance coupling member in said first and the duration of the period other part is controlled independently of said time constant so that one of the said period parts is stable, and further wherein said second coupling member a Impedance c of the impedances in such an arrangement and of such magnitude in the cathode circuits of the tubes mentioned that no current can flow between the cathode and control grid of each tube during operation (Fig. ι and 2). 2. Electrical circuit arrangement according to claim 1, characterized in that said second coupling element contains resistance impedances (R ₃ , R _t ) in such an arrangement and of such size in the cathode circuits of said tubes that in operation there is essentially no current between the cathode and control grid each tube can flow, and wherein the duration of one of said period parts is determined by the time constant of a circuit with the resistance impedance (R ₃ , R _t ) in the cathode circuit of one of said tubes and with capacitance (C) between said cathodes and the Duration of the other period part is determined independently of the time constant of said capacitance and the resistance impedance in the cathode circuit of the other tube so that the last-mentioned period part is stable (Fig. 1 and 2). 3. Electrical circuit arrangement according to claim i, characterized in that said tubes have a common cathode impedance (R ₅ ) and the difference in the bias voltages applied to said tubes is so great that said period part is made stable (Fig. 3 to 6). 4. Electrical circuit arrangement according to claim 2, characterized in that said Capacitance (C) is connected in parallel to a one-sided conductive device (3) which is set up in this way is that it conducts at a suitable time to make the said period part stable (Fig. I). 1 sheet of drawings 2073 10.