DE1219979B - Electronic counter with a multi-cathode counter tube - Google Patents

Description

Electronic counter with a multi-cathode counter tube addition to the Patent: 1158 567 The invention relates to improvements in the main patent 1158 567 described circuit arrangement with an electronic counter concerns a multi-cathode counter tube.

The multi-cathode counter tube of this counter described in the main patent works as a display tube and is equipped with cold cathodes. Also contains the electronic counter described in the main patent still has a plurality of cold cathode trigger tubes, each of which is connected to a cathode of the display tube in such a way that the display tube cathode, which is connected to a current-permeable trigger tube stands, glows, whereby when an input pulse is received the current-permeable The trigger tube is extinguished and the next trigger tube is ignited.

The circuit arrangement described in the main patent is characterized by that uses an indicator tube with longer deionization time than the trigger tubes and each cathode of the display tube with the trigger electrode of the next Cathode of the display tube associated trigger tube is coupled in such a way that voltage fluctuations, which at the anode of the display tube after extinction of the discharge between their Anode and one of its cathodes occur as a result of the latter being cathode still flowing deionization current to the trigger electrode of the next one Trigger tube are transmitted.

The present invention is based on the object of an electronic Specify counter according to the main patent, which protects against fluctuations in the characteristics of the Trigger tubes is less sensitive than @lie circuit arrangement described in the main patent.

! The invention is based on an electronic counter with all Features of the main claim of the main patent and is characterized by Mitfel to limit the negative potential fluctuations at the Release electrodes of the release tubes.

These means should preferably be devices that are current-permeable on one side and consist, for example, of one semiconductor diode each. Preferably should also the. Anode each trigger tube through a resistor to a point be connected to positive potential.

An embodiment of the invention is described below with reference to the drawing described.

F i g. 1 is a circuit diagram of an embodiment of the invention, and F i g. 2 is a representation of the time course of various voltages, which relates to the circuit arrangement according to FIG. 1.

The in F i g. The ring counter shown in FIG. 1 contains a multi-cathode counter tube 1 which operates as a display tube and whose anode 7 is connected via a resistor 8 to a source V3 of positive potential. The display tube 1 has ten cathodes, denoted by the numerals 0 to 9. In Fig. 1, only the cathodes with the reference numerals 0, 1, 8 and 9 are shown.

Each of the cathodes of the display tube is directly connected to the anode of the associated trigger tube. In Fig. 1 are just the trigger tubes 2, 3, 4th and 5 which are connected to cathodes 0, 1, 8 and 9 of the display tube are connected.

The cathodes 1 to 9 of the display tube are number-shaped, and the associated trigger tubes 3 to 5 have a common cathode resistor 20, which in turn is connected to the negative terminal VO of the voltage source already mentioned above. The trigger tube 2 connected to the cathode 0 has its own cathode resistor 21.

The size of the voltage difference between the terminals V. and V, is chosen so that a glow discharge between the anode and a cathode of the Display tube and maintained between the anode and the cathode of the associated trigger tube will. The voltage drop across resistor 8, i. H. the voltage difference between the terminals V3 and V3 regulates the discharge current to such a value that the Cathode of the display tube to which discharge current flows through the glow discharge is completely covered. The size of the resistors 20 and 21 is chosen so that the voltage drops across these resistors are small compared to the voltage drop at the resistor 8 are.

The anode of each trigger tube is capacitive with the trigger electrode coupled to the next following trigger tube in the whole ring counter. So it lies a capacitor 14 between the anode of the trigger tube 2 and the trigger electrode the trigger tube 3; a capacitor 16 between the release electrode of the release tube 4 and the anode of the preceding trigger tube; a capacitor 18 between the Anode of the trigger tube 4 and the trigger electrode of the trigger tube 5 and finally a capacitor 12 between the anode of the trigger tube 5 and the trigger electrode the trigger tube 2. Furthermore, each trigger electrode has its own resistor connected to a bias voltage source V2. There are thus the resistors 13, 15, 17 and 19 are connected to the trigger electrodes of the trigger tubes 2, 3, 4 and 5. the The size of the voltage V2 is chosen so that the potential between the trigger electrode and the cathode of each trigger tube is normally below the ignition value of the relevant one Trigger tube lies. A diode D2, D3 and is connected to each of the resistors mentioned D4, each in turn with the relevant resistor 15, 17 and 19 in series is connected, in parallel. The series circuit is connected to the resistor 13 of the trigger tube 2 a diode D1 and a resistor 38 connected in parallel.

If the relevant positive operating voltage is connected to terminal V3 is, ignites the discharge path between the anode 7 and one of the cathodes of the Display tube and also the anode-cathode route of the associated trigger tube. The corresponding drop in potential at the anode 7 causes that in the display tube only current flows to a cathode. The glow discharge can then by means of one of the Terminal 26 applied pulse from the respective, glowing cathode of the display tube be transferred to the next following cathode.

The anode of each trigger tube is through a resistor 28, 29, 30 and 31 connected to the connection line between two resistors 36 and 37, which form a voltage divider between terminals V3 and V. So it lies the resistor 28 between the anode of the trigger tube 2 and the mentioned connecting line, while resistor 29 is the anode of trigger tube 3, resistor 30 is the anode the trigger tube 4 and the resistor 31 the anode of the trigger tube 5 with the mentioned Connecting line connects. The sizes of the resistors 36 and 37 are chosen so that their connecting line is at a positive potential V9 of about 300 volts is located. The sizes of the resistors 28 to 31 are much larger than the sizes of resistors 13, 15, 17 and 19.

The grid of a hot cathode three-pole tube 6 is connected to a terminal 26, and the anode of this three-pole tube is connected to the anode 7 of the display tube 1 through a resistor 9. The cathode of the three-pole tube 6 is connected to a bias voltage V1, the size of which is selected so that the tube 6 does not carry any current when the terminal 26 is at the potential V i. If, however, the potential at the terminal 26 is raised to the value V 7 , as indicated by the voltage curve (a) in FIG. 2 is indicated, the tube 6 is current-permeable. If the input pulse has a duration of t1 to t2, the potential at the anode 7 of the display tube changes in accordance with the voltage curve (b) in FIG. 2. It can be seen from this voltage curve (b) that the anode potential initially falls to a value V4, which is sufficiently low below the normal anode potential V3, as a result of the additional current flowing through the resistors 8 and 9 and the anode-cathode section of the tube 6 falls off; in order to ensure that the potential difference at the above-mentioned two discharge paths connected in series is now too low to continue to maintain the discharge over these two discharge paths. The difference between potentials V3 and V4 exceeds the normal voltage drop across resistor 20 (or 21) and the duration between t1 and t2 is longer than the deionization time of the trigger tubes but shorter than the deionization time of the display tube.

Assuming that the trigger tube 2 is initially current-permeable may be, then the capacitor 14, the upper assignment of which is at a potential V, of about 180 volts and its lower assignment is practically at the potential V2 is charged. When the potential of the anode of the display tube drops, The capacitor 14 discharges quickly through the anode-cathode path of the trigger tube 2, resistor 21 and diode D2. As a result of the rapid discharge of the capacitor 14, the potential at the anode of the trigger tube 2 drops rapidly, and if so the operating voltage of the tube 2 is undershot, this tube goes out. While the discharge of the capacitor 14 is the potential at the trigger electrode of the Trigger tube 3 kept practically at the value V2, as can be seen from curve (d) in F i G. 2 emerges. When the trigger tube 2 goes out, the will start charging again Capacitor 14 via resistor 28, but the time constant of this charging, d. H. the product of the resistor 28 and the capacitance of the capacitor 14 is so high is that no appreciable increase in voltage across capacitor 14 up to the point in time t2 comes about.

At the time t2, the tube 6 goes out, so that its anode potential rises, and the potential of the anode 7 rises to a value between V3 and V3, since no trigger tube is current-permeable at this time. At this time, the discharge path between the anode 7 and the cathode 0 of the display tube is still ionized, and accordingly, since the anode potential of the display tube rises, a small current flows to the cathode 0, with the result that the potential of this cathode is simultaneous with the potential the anode 7 increases. This increase in potential is transmitted to the release electrode of the release tube 3 via the capacitor 14. The potential at the bottom of the capacitor 14 and thus also the potential of the release electrode of the tube 3 rises to the value V6, and the discharge path between the release electrode and the cathode of the tube 3 ignites with the result that the main discharge path of this release tube and the Also ignite the discharge path between the anode and the cathode 1 of the display tube. The cathode 1 of the display tube is thus covered with a glow layer, and the potential of the anode 7 drops again to the value V3. The capacitor 14 is initially charged via the resistor 15 and via the still ionized discharge path between the anode 7 and the cathode 0 . The time constant of 14 and 15 is large compared to the time constant of 14 and Dz, but small compared to the time period from t1 to t2, so that the voltage curve across resistor 15 corresponds to (d) in FIG. 2 has the course shown. If the discharge path between the anode 7 and the cathode 0 is deionized, the capacitor 14 continues to charge at a much slower rate via the resistor 28 until the lower assignment of this capacitor is practically at the potential V2 and the upper assignment is at the Potential V9 is.

It can be seen that at time t1, the anode of each trigger tube Except for the anode of the live trigger tube 2 is at a potential V9 is located so that each of the coupling capacitors except the capacitor 14 is charged to the voltage difference V9-V2. The diminution of potential the anode 7 has practically no influence on the potential of the anode of one of the blocked Trigger tubes off, and therefore the charge on none of the coupling capacitors changes either with the exception of the capacitor 14; thus the potential will not apply to any of the cathodes Change 1 to 9 significantly so that one of the trigger electrodes is one of the trigger tubes With the exception of the tube 3, the pulse supplied is too small to cover the discharge path to ignite between the trigger electrode and the cathode of this tube.

The processes described lead to the activation of the trigger tube 3 in place of the trigger tube 2 and for the transition of the glow discharge from the cathode 0 to cathode 1 in the display tube. Another input impulse transfers the Glow discharge on the cathode 2 etc., until finally the glow discharge on the Cathode 9 arrives, from where it returns to cathode 0 again.

Claims (4)

Claims: 1. Electronic counter with a multi-cathode counter tube with cold cathodes as the display tube, in which a plurality of cold cathode trigger tubes is present, each of which is connected to a cathode of the display tube in this way is that the display tube cathode, with a current-permeable trigger tube is connected, glows, and when an input pulse is received, the respective current-permeable trigger tube extinguished and the next trigger tube ignited and which also has a display tube with a longer deionization time is used as the trigger tubes and each cathode of the display tube with the trigger electrode so coupled to the trigger tube associated with the next cathode of the display tube is that voltage fluctuations that occur at the anode of the display tube after extinguishing the discharge occur between its anode and one of its cathodes, as a result of the to this latter cathode still flowing deionization current to the trigger electrode the next following trigger tube are transferred, according to patent 1158 567, g e -marked by means of limiting the potential fluctuations running in the negative direction on the release electrodes of the release tubes (2 to 5). 2. Electronic counter after Claim 1, characterized in that for each trigger tube (2 to 5) these means each from a one-sided current-permeable device, for example from one each Semiconductor diode (Dl to D4 exist. 3. Electronic counter according to claim 1 or 2, characterized in that the anode of each trigger tube (2 to 5) with a fixed positive potential. 4. Electronic counter according to claim 3, characterized in that the anode of each trigger tube (2 to 5) has a Resistor (28 to 31) connected to the tapping point of a voltage divider (37, 36) is.