DE548916C - Tiltable electron tube circuit with two stable equilibrium positions, especially for recording and registering one-time, very fast processes, e.g. B. with the cathode ray oscillograph - Google Patents

Description

Tiltable electron tube circuit with two stable equilibrium positions, especially for recording and registering unique, very fast processes, e.g. B. with the cathode ray oscilloscope For recording and recording of one-off, very fast processes, especially by means of cathode ray oscillographs, for Tripping of relays by electrical surges of very short duration, etc. are different tiltable electron tube circuits have become known. Such circuits must be used if you don't know the exact time of the onset of the process can influence arbitrarily; this is not only the case with registration involuntarily triggered processes, e.g. B. with lightning, but also with all those arbitrarily triggered processes in which the duration of the process to be recorded itself is very small, compared to the inevitable inertia delays and Inaccuracies in the triggering switching action, e.g. B. when recording traveling waves, which are to be triggered by mechanical switches.

For recording and recording such one-offs, very quickly The tiltable electron tube circuit must have two stable processes in progress Have equilibrium positions, d. H. it must be held indefinitely in every tilted position can be.

In order to achieve the desired, To achieve very low tipping time, the damaging capacities, in particular, must the grid capacity of the tubes used should be as small as possible.

There are so far toggle relay circuits with space charge grid tubes and those with single-mesh tubes have become known. Of these have single-grille tubes a considerably smaller grid capacity than space-charge grid tubes, but with the previous ones known circuits with single grid tubes is the trigger point of the trigger circuit directly connected to the shock wave line. and there is the potential of the point of impact considerably during the tilting process compared to the potential of the heating filaments of the tubes changes, the entire shock wave line must be charged during the tilting process will. The time required for this is so great that the advantage of the less The grid capacity of single grid tubes is completely lost again.

One has therefore dispensed with single-mesh tubes despite their other advantages and circuits with space charge grid tubes that have a fairly high grid capacitance own, used. Such flip-flops with Rauinladegitterröhren are z. B. in an essay by Gäbor, published in volume i of the »research books of the Study Society for High Voltage Systems «, issued in September 1921, given on page 40. In these known circuits, the grid is that changes its potential during the tilting process (the control grid) of your actual bumper grille (the space loading grille) separated. This is natural the whole circuit complicated. In addition, the known space loading grid tubes still have the disadvantage that they may not have a sufficiently high anode current own.

The subject of the invention is a tiltable electron tube circuit, which is characterized by a very short tipping time. This is achieved by that single-grid tubes are used in a manner known per se, and that the surge voltage inductive, capacitive via a gas discharge path or via valve cells at two points the flip-flop is fed, one of which will be during the flip-flop process Potential towards the filaments of the tube does not change.

This enables the low capacity as well as the others To be able to use the advantages of single-grid tubes without the known circuits having to accept the disadvantages associated with single-mesh tubes.

In itself is the connection of a capacitor between the grid and Initiation already in the mentioned essay by Gäbo r on page 42, but only specified for a circuit with space charge net tubes. . The capacitor has here, In contrast to the invention, the only task is to prevent one from being too large current is taken from the impulse line.

The invention will be explained in more detail with reference to the accompanying drawings will.

In Fig. R, i and 2 are the tilting tubes, their anodes and grids are mutually connected via the capacitors 3 and 4. To the capacitor 4, the battery voltage 7 is applied via the resistors 5 and 6. The resistances 5 and 6 allow the grid potential of the tube i to change momentarily can, .without the battery 7 making this change. At resistors 8 and 9, when the tube emission changes, the voltage jumps that are necessary for the working of the circuit should be used. The resistance io is the so-called Resistance to tilt back, the purpose of which is to restore the tube 2 after it has been tilted after a certain time to bring to the `emission. This is achieved by that the resistance io brings the grid of the tube back to zero potential. The surge voltage et, which is applied to the resistor 12, -w is across the capacitor r i the control grid of the tube 2, which should emit fully before the tilting process, supplied .. The capacitor i i causes the desired separation of the point of impact from the shock wave line. This can therefore be connected on one side to the earth potential will.

A resistor 13 is expediently connected between the resistor 12 and the isolating capacitor ii, then momentary changes in the grid potential are also possible if the voltage at the connection point of the resistors 12, 13 is held without the capacitor ii changing its charge.

The connection of the Braun tube to the toggle relay takes place, for example in such a way that on the grid of the tube i, the potential due to the tilting process changes, the grid of a deflection tube 36 is connected. At the anode of this Tube is a capacitance 37 as well as the time deflection plate of the cathode ray oscilloscope 38. The capacitors 37 and 38 are connected to a high-resistance resistor 39 DC voltage connected. Before the tilting process, the grid potential is the Deflection tube 36 such that the tube is blocked. Due to the jump in tension in the The tilting process begins to emit the tube, thereby discharging the capacitor 37. The resulting change in tension on the time deflection plates moves the Cathode ray at the desired speed. The tube 36 is here at the same time represents the resistance through which the capacitor 37 is discharged.

The circuit according to Fig. I only works with negative voltage surges. If one also wants to make the arrangement respond by positive impacts, as is particularly necessary in the case of thunderstorm registrations, a circuit according to Fig. 2 must be used. The circuit of the two tilting tubes i and 2 is exactly the same as in Fig. R. In order to ensure that the circuit responds even to positive surges, a third tube r4 is used. The surge voltage et is now separated from the corresponding control grids by the two capacitors ri and 15 and by the resistor 13.

As soon as a positive collision occurs, the grid potential is raised of the tube 14 begin to emit these and thereby the anode potential of the Tube? as well as reduce the grid potential of the tube 2 via the capacitor 3, so that the tube 2 is blocked.

It can now happen that with a positive shock the Grid potential of the tube 2 through direct influence via the capacitor ii is raised so that one Blocking of the tube by the influence via tube 1: I is no longer possible. To avoid this, according to the further invention the ratio of the capacitors i i and 1 5 chosen so that A positive switching surge is stronger via the capacitor 15 and the tube 14. affects than on a direct route through the capacitor - i. This is in the present Trap achieved by reducing the capacitor ii compared to the capacitor 15.

Furthermore, one of the resistors 33 and 35 as well as is shown in Fig. 2 the glow lamp 35 shown existing display device, which recognize later lets whether the toggle relay has responded. This is e.g. B. then necessary if after every time it is triggered, the resistance io tilts back into the ready position to be held. The display device works roughly as follows: In the idle state the voltage of the glow lamp lies between the extinguishing and ignition voltage. Once the arrangement tilts, the ignition voltage of the glow lamp is exceeded, so that the lamp burns. If the arrangement now tilts back to its previous state, the glow lamp goes out no longer, since the erasing voltage is not undershot. Only by switching off the lamp can be switched off by means of a switch.

Instead of the display device shown, a different one can also be used suitable optical, acoustic or registering display device is used be e.g. B. a drop flap relay.

In Fig. 3 an embodiment of the invention is shown, in which the surge voltage from the corresponding grids by interposing a Transformer is disconnected.

The circuit according to Fig.3 works similarly to that in Fig. I and 2 shown. Separate anode batteries 2.2 are provided for the two tubes 16 and 17 and 23 provided. The anode voltage of the tube 16 becomes the grid 1; on the Condenser 18 is supplied. The resistors i9 and 21 correspond to the resistors 8 and 9 of the circuits described above. The required resistances arise at these resistances Voltage jumps. The resistance 2o causes the tilting back. The grid of the tube 16 receives a bias voltage 27, which in the manner described earlier via the resistors 25, 26 is fed to the capacitor 2d. The surge voltage is the grid of the tube 16 fed through the transformer 28, so that a change in potential of the shock wave line does not occur during the tipping process. Another embodiment of the invention that Applying surge voltage to the trigger relay consists of a rectifier or a glow lamp in the lead leading to the bump electrode. When using rectifiers (High vacuum valve tubes, glow light rectifiers) the circuit must be created in this way that no current can flow through the rectifier in the normal state.

But you can also use ionization tubes without a rectifier effect by if the ignition and extinction voltage is used, use it. In Fig.q. is an embodiment shown such an arrangement.

The circuit works exactly like that shown in Figs. The resistors 8 and 9 and the capacitors 3 and q. correspond to the resistors and capacitors identified in the above figures. The surge voltage will. fed via the glow tubes 29 and 30. The ignition voltage of the glow tubes should z. B. be above 8o volts. In the idle state of the circuit, in which the tube 2 emits, but the tube i, on the other hand, does not allow an anode current to pass, the grid of the tube i has a voltage of about -80 volts. This value results from the anode voltage of zoo volts, an ohmic voltage drop of about 100 volts in resistor 9 and a voltage of - 180 volts across the capacitor .4. The grid of the tube 2 has approximately earth potential. In the idle state there is therefore a voltage of about 80 volts on both glow tubes, and that on the lamp by interposing the battery 31. However, this voltage should not be sufficient for ignition.

As soon; a positive surge occurs, the ignition voltage of the glow lamp 29 is exceeded and the tube i begins to emit. The voltage of the lamp 30 is reduced by the same shock, so that this lamp cannot ignite. Conversely, only the glow lamp 30 ignites in the event of a negative surge.

Uin the harmful capacitance between the electrodes of the tubes as well to press as small a value as possible between the connecting lines According to the further invention, the electrodes and some or all of the switching elements be combined in a manner known per se in a multiple tube.

To simplify operation, you can also adjust the anode voltage and the heating voltage to the lighting network via a transformer and rectifier or with DC voltage via a voltage divider. Then the awkward one falls Maintenance, which is necessary for operation with accumulators, gone.

If it proves necessary for circuit reasons, Bringing the filaments of the tubes to different potentials, this can be done in known way by direct current series heating all Licher tubes with or be affected without a power supply unit or when connected to the AC power supply, that a separate heating coil is provided on the power supply unit for each tube will.

When recording heavy current processes, e.g. B. traveling wave vibrations in power lines, it has often been observed that by direct influence the strong magnetic and electric fields an unwanted tilting of the electron tube circuit occurred. These disturbances can be avoided in that the entire toggle relay or individual parts of the same against these external influences by covering them with Copper and iron layers (sheets, wire nets, etc.) is protected.

Claims (5)

PATENT CLAIMS: i. Tiltable electron tube circuit with two stable equilibrium, especially for recording and registering one-off, very fast processes, e.g. B. with the cathode ray oscillograph, characterized in that that on the one hand to reduce the capacity in order to achieve a low tipping time Single-mesh tubes are used, on the other hand the surge voltage inductive, capacitive two points of the toggle switch via a gas discharge path or via valve cells is supplied, one of which is opposite its potential during the tilting process does not change the filaments of the tubes. 2. Tiltable electron tube circuit according to claim i, characterized in that when using several tubes (i, 2 and 14) for the purpose of avoiding undesirable influences, the capacitance of the isolating capacitors (11, 15) belonging to the individual tubes is dimensioned differently, that a positive shock via the positive shock tube (i4) has a stronger effect on the grid of the tube (2) to be blocked than directly via the separating capacitor (ii) belonging to the tube (2). 3. Tiltable electron tube circuit according to Claims 1 and 2, characterized in that that all or some of the electrodes and the switching elements are known per se Way are combined in a multiple tube. 4. Tiltable electron tube circuit according to claims i to 3, in which a device for displaying the tilting process is provided, characterized by such a design of the display device, that even after the tilting arrangement has returned to the standby position on optical, acoustic or registering ways it can be seen whether the toggle relay has been addressed Has. 5. Tiltable electron tube circuit according to claim 4, characterized in that that in the display device a glow lamp (35) is provided which is switched in this way is that their voltage in the quiescent state of the circuit between ignition and extinction voltage lies.