DE487039C - Electric double ignition - Google Patents

Description

Electric double igniter The invention relates to a further embodiment of the electric detonator specified in patent 486942, which is there in training as Time fuse or as a percussion fuse with pipe fuse two with means for changing the voltage their storage energy contains capacitors provided against each other, their between their poles of the same name only increase to the ignition voltage level after a certain time Voltage difference is used to ignite the ignition means. - Building on this Capacitor arrangement, the invention creates a simple, purely electric double igniter with in-line impact ignition, after which the. due to uneven discharge of the two capacitors between their poles of the same name sawohl for the timing ignition as well as for the impact ignition; dunb is used. Here is into which the gleidhnami; gen poles of the two capacitors are connected by an ignition means Line of an electrically operating relay, e.t <especially a spark gap or a high-resistance one Resistance, placed, and the spark gap or resistance is through a make contact made short-circuitable. Or you can use a different clock form of the invention caused by the uneven discharge of the two capacitors between: voltage difference arising from their poles of the same name only for impact ignition, on the other hand, the discharge current of one of the two candlesticks for time ignition. To this The purpose is in the equalizing ignition circuit between the poles of the same name of the two Capacitors an open ignition contact switched on and one of the two capacitors is closed to give the time ignition via a variable resistor and the ignition means.

The drawing illustrates the circuit diagrams in Figs. R to 7 several embodiments of double detonators according to the invention.

The detonators of all embodiments each contain two capacitors c and. d with the assignments c1, c. and dl, d_ The two capacitors c and d one Detonators are charged to the same voltage. This can be done either by means of one with the Ge; -sc: hoß firmly connected. or separated from a vam Gesc: hoß Power source from. Success, like the latter with the double igniter according to Fig. I shown is. For this purpose, there are three against each other and against the wall of the floor on the outside of the floor jacket isolated contacts x1, x2, x3 attached. The contact x is with the assignments cl and d; of the two capacitors :, x, with the assignment c. of the capacitor c and x. conductively connected to the occupancy d2 of the capacitor d. The contact x1 is for example to the positive pole, never contacts x2 and x3 are to the negative pole of the Power source not shown here, separate from the storey, can be connected.

The two assignments dl, d2 of a capacitor d are on the hochahmi: gen resistance q closed. The two assignments charged with the same name 4 of the capacitor d and c. des. Capacitor c are over a normally open Aufsdhlagschlie.ßko.ntakt p, the line o and a flat heating wire containing Bridge glow igniter m connected to one another. In addition, between the occupancy cl of the second capacitor c and the ignition means nz a high-resistance Rege1-ividerstand t switched.

d2, p, o, m, c. is the Aufsc: hlagzünids! tromkreis; cl, i, in, c2 the time ignition circuit. Appropriately, a switch (not shown here) is placed in the timing control unit, which connects this circuit up to. after charging the capacitors and removing the power source from. the latter keeps geäffniet and closes automatically in training as an inertia or centrifugal switch only after the Gesichoßverschuß.

After the projectile has been fired, one capacitor discharges d over the resistance g, so d @ ate gradually between the. charged with the same name Assignments d2 and c. between the two capacitors a voltage difference increases. The resistance g is dimensioned so that between the occupancy ends. and c2 a .zur Immediate ignition of the ignition means with sufficient voltage only then after the projectile has already left the gun barrel and is in proper position Distance from it, so that in the event of a premature closure of the impact contact p immediate ignition of the ignition agent can occur. The impact ignition device is therefore pipe-safe; only occurs after this security period has elapsed an instantaneous ignition when the impact contact p now closes a.

At the same time, the second capacitor c discharges via the variable resistor t and the ignition means m, depending on ain. Resistance t is set to a larger or smaller resistance value, the discharge of the capacitor C takes place more slowly or more quickly, the heating wire of the ignition means m is heated to the temperature required to ignite the ignition material after a shorter or longer time, and an 'earlier or later' is obtained Ignition timing.

The resistance value of the constant resistance g in the discharge circuit one of the capacitors d is smaller than the one at the resistor t in the discharge circuit of the second capacitor c is the smallest adjustable resistance variable. This will turn out to be the capacitor d always discharges faster than the capacitor causing the time ignition c and it always grows between the poles of the same name before the timing occurs c2 and d2 of the two. Capacitors c and d: one when the impact contact is closed beforehand p Sufficient voltage difference for immediate impact ignition on. After, one Failure of the time ignition and impact of the projectile on the ground occurs since meanwhile Both capacitors have become dead, no more surcharge one, which is particularly advantageous when fighting aircraft in one's own country.

Occasionally, especially when shooting at or overshooting enemy-occupied terrain, it is desirable, however, that after the time ignition has failed, the projectile detonates when it subsequently hits the ground. The circuit diagram of such a double igniter is shown in Fig. 2. - The general circuit of the igniter capacitors corresponds to that of the above-described embodiment according to Fig. I. However, in Fig. 2, one capacitor d is not closed via a special resistor, but also via the variable resistor t. The constant resistance value in the discharge current circuit of the capacitor d is always greater than the arbitrarily adjustable resistance value in the time ignition circuit .c1, t, in, c @. Even if the time ignition fails, there is a voltage difference between the two capacitors c and d which is sufficient for flash ignition.

The above-mentioned ignition ratio, namely that before it occurs the time ignition and after it. Failure on subsequent bullet impact on a target. an impact ignition either not at all or only. for a short time after a clean set ignition point or at all afterwards, too later occurrence of this gas shot can be replaced by the vorbeschrebene various votes; of the resistances t and g in the discharge circuits of the two capacitors c and d also by different dimensioning of the capacities of the two capacitors can be achieved.

The circuit diagrams of the exemplary embodiments according to Figures 3 and q. correspond in the general arrangement and mode of operation to those according to Figs. i and z, but with the modification that in the impact ignition circuit 12, p. o, c, and in the Zeitzündstromkreiscl, t, e2 each a special Zündmittelml and tn., is connected. The Zündmittelm. In the ZeitzliridstYOmkreis is a bridge glow igniter with heating wire, the ignition means ml in the impact ignition circuit can either be a bridge glow igniter or, advantageously, a radio igniter.

In the embodiment of Fig. 3 are the. poles of the same name d2 and c. of the two capacitors c and d via the impact contact p, the line o and the ignition means m, a bridge glow igniter, connected to one another. aside from that is the capacitor c due to the high-impedance variable resistor t via the ignition means m closed. After the G: eschasse has been fired, the capacitor c discharges depending on the resistance value set at t via the ignition means m faster or slower and you get an earlier or later ignition point. The condenser d loses only a little of its voltage through self-discharge. With suitable dimensioning the capacitance of the two capacitors c and d, their charging voltage and the resistance t can be achieved that shortly after the Ahsehuss, i. H. after the course of the Pipe safety of the igniter necessary safety period between. the eponymous Poles c "and d. Pound before the ignition point set for time ignition occurs a tension has grown, which with a now closing of the Aufschlagkoütaktsp when the bullet hits a target, the ignition agent ignites immediately m causes. Impact ignition is also possible after a failure of the time ignition, since the capacitor d lost only a little of its voltage through self-discharge asked and at a closing; of the impact contact p now via the ignition means m discharges to capacitor c.

In the embodiment according to Fig. 6, the capacitor c is closed by a constant resistance t across the ignition means m . The timing of the time ignition device takes place here by different measurements of the capacitors c and d: charging voltage. In the case of a higher charging voltage, a current of greater magnitude flows in the discharge current krenscl, t, m, c, of one capacitor c, and a current of greater magnitude flows when the charge voltage is lower, so that an earlier or later ignition point is achieved. Like the igniter described above according to Fig. 5, the double igniter according to Fig.6 is pipe-safe; Impact ignition is possible both before the timing ignition occurs and if it fails afterwards.

In the case of the double detonator according to Fig. 7, the assignments charged with the same name are c2, & of the two capacitors c and d through the line o via a spark gap a and an ignition means m, which can be a radio igniter or a bridge glow igniter: connected with each other. The Fwnkenstreckeu can be short-circuited by an impact contact p. The two occupancy of one of the two capacitors, z. B. that of the condenser, d, are connected to one another through the high resistance g. This serves due to the discharge of one capacitor d between the poles of the same name t12, c2 of the two capacitors d and c after the projectile has been fired gradually growing Voltage difference to both time ignition and impact ignition.

d2, u, m, c2 is the time ignition circuit:;. d2, p, o, m, e2 is the impact ignition circuit. The timing of the time ignition device is carried out by different measurements of the charging voltage applied to the two capacitors c and d. Depending on the size of the charging voltage, one capacitor d discharges faster or slower via the resistor g and sooner or later a voltage sufficient to break down the spark gap u occurs between the poles d2 and c2 of the same name, and thus the ignition of the ignition device causing current flow through this. When the projectile hits a target, the spark gap u is short-circuited. S, en. If this takes place before the set time ignition occurs, the voltage difference that has meanwhile increased between the two capacitors is sufficient to send a current sufficient for its immediate ignition via the ignition means m.

Claims (6)

PATENT CLAIMS: i. Electric double igniter according to patent 486942, characterized in that the uneven discharge of the two capacitors (c, d, Fig. 7) between their poles of the same name (d2, c2) by interposing a pure spark gap (u) or a high-ohm resistor Sawohl for the time ignition as well as through the spark gap (u) or the ho-chohmi.-gen Resistance on impact, the projectile short-circuiting impact contact (p) - serves for impact ignition. 2. igniter according to claim i, characterized marked, that caused by the uneven discharge of the two capacitors between their Pole of the same name arising only for impact ignition, on the other hand. the discharge current of one of the two capacitors is used for time ignition. 3. Double igniter according to claim 2, characterized in that the poles of the same name (c2, d2, Fig. I) of the two capacitors (c, d) are connected to one another via an impact contact (p) and an ignition means (m), as well as the one Capacitor ,, (d) via a high-resistance resistor (g) and the second capacitor (c) via .ein variable resistor (i) and the ignition means (m) is closed. q .. Double detonator after Claim 3, characterized in that the one capacitor (d, Fig. A) by the The rheostat (t) is closed, which in the over the ignition means (in) leading l; ntladestromkreis the second capacitor (c) is switched on. 5. Double igniter according to claim 3, characterized in that the two poles of the same name (c2, d2, Fig. 5 and 6) of the two capacitors (c, d ) are connected to one another via an impact contact (p) and an ignition means (m) and one capacitor (c) is closed via a high-ohmic constant or adjustable resistor (1i, Fig. 6, or t, Fig. 5). 6. Double igniter according to claim 2 to 5, dadurdb- characterized in that in the Aufschlag Zündstromkreis (compensation circuit_) between the same poles (cl, dl, Fig.3 and ¢) of the two capacitors (c, d) and in the time ignition circuit (discharge circuit) of the one Capacitor (c) a special ignition means (ml or in.) Is arranged.