DE1948382A1 - Arrangement for generating an electrical pulse - Google Patents

Description

"Arrangement for generating an electrical pulse" The invention relates to an arrangement for generating an electrical pulse at a point in time its time interval to the preceding, arbitrarily selectable closing time a switching device can be specified.

Known arrangements of this type are used in an electric time fuse for expendable explosive charges the generation of the ignition pulse through which the Ignition of the explosive charge triggered after a predetermined time after launch will.

The invention is also particularly advantageous in electric time fuzes Can be used for explosive charges to generate the respective ignition pulse if it this can be a stationary explosive charge (land or sea mines) or even around the explosive charges of grenades, bombs, and torpedoes like that. The latter type of explosive charge d. H.

which are not stationary. is not shootable in contrast to the above Type of shootable explosive charge.

Fig. 1 shows the basic circuit diagram of a known arrangement for use in time fuses. A capacitor C1 is used as plug contacts before the conclusion shown, in practice mostly designed as sliding contacts connecting means charged to the voltage of the generator G. At the same tension a another approximately equal capacitor C2 charged. A switch S is as Acceleration switch is formed and is activated by the slug acceleration upon completion or closed shortly thereafter, so that the capacitor C2 is via a resistor R discharges. When it is fired, the electrical connection to the generator is established at the same time G solved the Yes is stationary. O2 decreased during the discharge of the capacitor the voltage across the capacitor is very insignificant. By means of a threshold switch the voltage difference between the two capacitors is monitored. Exceeds the threshold value switch maintains this differential voltage at a predetermined value through so that the capacitor 02 over the Ignition element from the capacitor C1 is reloaded. The resulting charging current ignites the ignition element. The disadvantage of this type of circuit is that only a small part of the stored Energy can be used as ignition energy.

A second known arrangement for use in time fuses works according to the basic circuit diagram of FIG. 2. In this arrangement, before firing nwn the capacitor C1 charged, since the switching device X, which in turn as Accelerator switch is designed to be opened and only during this charging is closed after the launch. Therefore, the capacitor C2 is only recharging Close the switching device S from the capacitor C1. Reaches the charging voltage of the capacitor C2 a predetermined value, a threshold switch switches through, so that the capacitor C2 is discharged through the ignition element and its ignition causes.

This known arrangement also has the disadvantage that only a small one Part of the stored energy is used as ignition energy.

The invention is based on the object of providing an arrangement based on 1 and 2 to indicate the types mentioned with regard to the utilization of the stored Energy than ignition energy has a better efficiency.

The invention required an arrangement for generating an electrical Impulse at a point in time, its time interval to the previous one, arbitrary selectable closing time of a switching device by one before the closing time corresponding capacitor charging taking place can be predetermined by means of two storage capacitors and a discharge circuit. In an arrangement of the type mentioned above, there is the Invention is that the capacitance of the two capacitors is chosen to be unequal are that both capacitors are charged before the closing time, that both Capacitors in the discharge circuit are in series that the capacitor voltages are in the same direction in the discharge circuit at the beginning of the discharge and that as generation time of the pulse that point in time is determined after which the discharge is effected Closing the switching device the voltage across the capacitor with the smaller Capacitance has predetermined values in terms of its height and polarity, The ratio of the capacities of the two capacitors in the invention The arrangement is selected to be greater than 1.5, for example. Often found in the Practice when using the arrangement according to the invention in time fuses for anti-aircraft projectiles a Ratio of the two capacities from about 3 to 4.

The invention is not only for generating an ignition signal in time fuzes can be used advantageously but generally as a generator for a reference point in time Time-delayed pulses, with one pulse each time a switching device is closed is generated and laterally near the generated tone pulse, if necessary, a new one Capacitor charging must be carried out.

When using the arrangement according to the invention in a time fuse the switching device is preferably designed as an acceleration switch1 which - possibly delayed by a predetermined amount - to a predetermined maximum Flight acceleration or its time integral responds and closes.

It is particularly useful to use the two capacitors of the invention Charge the arrangement from a constant current source; is advantageous here the capacitor with the larger capacity a Zener diode of such polarity connected in parallel that this capacitor bi. charged to the zener diode voltage will. Furthermore it is expedient, the capacitor with the smaller one Capacity the series connection of an ohmic resistor with such a polarized one Connect diode in parallel so that this capacitor does not turn up after charging discharges through the ohmic resistance. The two capacitors are too, however can be charged from separate voltage and / or current sources; however, one then has the Disadvantage, instead of a total of two, at least three connection lines for having to work the charge.

The work resistance, above which the voltage of the pulse to be generated drops and when using the arrangement for generating an ignition pulse in a time fuse is a squib, is advantageously via the holding devices connected in parallel to the capacitor with the larger capacity. Here are measures to meet known type, which ensure that the switching devices close or are closed when the pulse is generated is. This point in time is identical to the point in time when the capacitor voltage of the capacitor with the smaller capacitance in terms of its height and polarity reaches or has their specified values representing the ignition criterion. This critical voltage across the capacitor with the smaller capacitance is particularly advantageous by means of a semiconductor circuit, preferably a Darlington circuit, determinable what the control path of the semiconductor circuit the capacitor with the smaller capacitance connected in parallel and the circuit operated in such a way that it is switched from the locked state to the conductive state as soon as the The time of generation of the pulse has come to protect the semiconductor circuit is expediently between the same and the capacitor connection point a diode to be provided, furthermore it is two-dimensional, another semiconductor circuit to use the discharge resistance via the discharge circuit from the time of generation of the pulse closes, Fig. 3 shows the basic diagram of an embodiment the invention. The capacitance of the capacitor C1 should be larger, for example that Be twice to ten times that of capacitor C2. First, both capacitors charged from the generators G1 and G2, the polarities of which are chosen so that the two capacitors in the closed switching device S via the discharge resistor R formed discharge circuit at the beginning of the discharge, capacitor voltages in the same direction exhibit that relate to this Add time. Preferably is the voltage of the generator G1 is constant, while that of the generator G2 is variable is; then, with the choice of the voltage of the generator from the outside, the temporal Specify the distance after which - calculated from the closing time of the Switching device 5 - a zero voltage detector (Fig, 3) closes the ignition switch SZ, so that thereupon the pulse to be generated is obtained, which in the embodiment of the invention according to FIG. 3 dae. ignition element there ignites. Again, the switching device S designed as a 3-speed switch when used in a time fuse. As from Fig. 4 showing the discharge voltage curves U01 and Uc2 of the capacitors shows the arrangement of Fig. 3 in a voltage-time diagram, it can be seen, Due to its smaller capacitance, the capacitor C2 discharges much faster than the capacitor C1 and changes in the vicinity of the ignition point tign its Polarity. The zero voltage detector closes the ignition switch SZ.

Used as a zero voltage detector and ignition switch if necessary only if a single transistor is used, it corresponds to that in capacitors C1 and C2 remaining residual voltage of the residual voltage of the transistor.

5 shows a detailed circuit diagram of an embodiment of the invention. The capacitors C1 and O2 are charged here from a constant current source K, where the capacitor voltage of the capacitor C1 at the end of charging is the same as Zener voltage of a Zener diode Z is, while the capacitor voltage of the capacitor C2 at the end of charging is essentially equal to the voltage drop across the resistor More precisely, RL is equal to this voltage drop plus the residual voltage a diode D1 preventing the capacitor C2 from discharging. Before closing the Sohaltvorriohtung S, which in turn as an acceleration switch in the time fuse Ausromquelle forms can be, the constant / K of the rest of the arrangement separated. When the switching device S is closed, the capacitors are discharging circuit across the Eatladewiderstand R to in series and the two capacitor voltages are at this point in time, as shown by the polarities on the capacitors emerges in the same direction. The transistor T serves as a zero voltage detector and ignition switch. After closing the switching device s it is still locked until its The emitter potential is more negative than its base potential. With the silicon transistor As is known, the emitter potential must be at least about 0.6 V below the base potential lie, so that with the doping of the transistor presupposed in FIG. 5, a collector current to the Flow is coming. As soon as the transistor T is switched to pass is, the capacitor C1 discharges through the load resistor, in the example via the ignition element.

From Fig. 6, which largely corresponds to the Fix 5, go advantageous Further developments of the arrangement according to FIG. 5 emerge. The designated in Fig. 5 with T The transistor is in the arrangement of FIG. 6 by a Darlington circuit two transistors T1 and T2 replaced, to which a resistor RD belongs. For protection this circuit against inadmissibly high base-emitter voltages is between this Circuit and the capacitor junction point the diode 3 is provided, a diode D2 prevents a discharge of the; Capacitor C1 in the event of a short circuit on the power supply.

In order to prevent the capacitor C2 from being carried by the base current of the Darlington circuit is discharged, is in the arrangement of FIG. 6 further a transistor T3 is provided, which connects the high-resistance discharge resistor R via the discharge circuit short-circuits as soon as the collector current of the Darlington pair starts a The voltage drop across the resistor RD causes the transistor T3 to pass switches.

The last-mentioned development of the invention, according to which the transistor T3 is also provided, greatly increases the work safety of the arrangement shown, Depending on the desired delay time of the generated pulse compared to the second closing point the switching device S is different in the arrangements according to FIGS. 5 and 6 high charging current impressed.

The arrangements according to the invention are advantageous as self-immolative igniters Can be used for shootable exposure charges such as projectiles and rockets, but equally as the time tinder of the other known species.

Claims (9)

P a t e n t a n s p r ü c h e order z; to generate an electrical impulse at a point in time its time interval to the previous, arbitrarily selectable, bottom casting time a switching device by a corresponding one taking place before the closing time Capacitor charging is predeterminable, by means of second storage capacitors and one Discharge circuit, in particular for use in an electric timer for Explosive charges for generating the ignition pulse, characterized in that the The capacities of the two capacitors are unequal - e.g. B. in proportion larger as 1.5 - are chosen that both capacitors are charged before the closing time be that both capacitors in the discharge circuit are in series that the capacitor voltages are in the same direction in the discharge circuit at the beginning of the discharge and that as generation time of the pulse that point in time is determined at which the voltage across the capacitor with the smaller capacitance given in terms of their height and polarity Has values. 2. Arrangement according to claim 1 when used in a lockable Time fuse, characterized in that the switching device is an acceleration switch is provided, which - possibly delayed to a predetermined extent - to a predetermined minimal flight acceleration or responds to its time integral and thereby closes. 3. Arrangement according to claim 1 or 2, characterized in that the two capacitors are charged from a constant current source, 4. Arrangement according to claim 3, characterized in that the capacitor with the larger capacitance a zener diode of such polarity is parallel. that this capacitor up is charged to the Zener voltage. 5. Arrangement according to claim 3 or 4, characterized in that the Capacitor with the smaller capacity is the Reth circuit of an ohmic resistor with such a polarized diode is in parallel that this capacitor is after the charge does not discharge the ohmic resistance. 6. The arrangement according to Anspruoh 1 bit 5, characterized in that the Working resistance of the arrangement over which the voltage the to generating pulse drops and when using the arrangement for generating a Ignition pulse in a time fuse whose ignition pill is via the holding device and the ignition switch connected in parallel to the capacitor with the larger capacity and that the ignition switch closes when the pulse is generated has come. 7. Arrangement according to claim 6, characterized in that the further Switching device is a semiconductor circuit. 8. Arrangement Mch claim 7, characterized in that the semiconductor circuit is a Darlington pair. 9. Arrangement according to claim 7 or 8, characterized in that to the debris of the semiconductor circuit between the same and the capacitor connection point a diode is provided 10, arrangement according to one of claims 7 to 9, characterized characterized in that a further semiconductor circuit is provided, which the discharge resistor in the discharge circuit from the moment the pulse is generated directly or via the Working resistance short-circuits in order to achieve a sufficiently large ignition pulse. L e r s e i t e