DE1578447A1 - ELECTRIC IGNITER - Google Patents

Description

BÖLKOW limited liability company Ottobrunn near Munich

Ottobrunn, June 29, 1967 BP 650 SX 1 Me / fe

Electric detonator .

The invention relates to an electric igniter for triggering of an ignition pulse after a preselectable delay time with a first capacitor as an energy store, which is connected to arming the detonator from an external energy source only for a short time Contacts is chargeable and discharges via a delay circuit to an ignition means.

Electric detonators which do not have an active energy source individually assigned to them are known. Such electric detonators have a capacitor as an energy store, which, for example, is built into one floor with the other components of the electrical ignition system. Leaves one If the launch tube is shot or immediately in front of it, the capacitor is connected to it via contacts that are connected to the Outer jacket of the projectile are brought out, charged by an active energy source firmly connected to the launch tube. . .

For example, from German patent specification 581 491 there is an electrical Known detonator, whose capacitor serving as an energy storage device via leads connected to its electrodes is connected to contacts attached to the outer surface of the projectile jacket in such a way that one electrode of the capacitor directly to the projectile jacket as a ground contact and the other electrode of the capacitor with one opposite the projectile jacket insulated contact he with the help of mechanical covering means only during the moment the electrical connection of the capacitor with the active energy source of the launch tube released and thus is protected against unwanted contact with the jacket of the launch tube after charging the capacitor « Such a mechanical cover of the opposite to the storey

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jacket-insulated contact is structurally complex and on the other hand not absolutely reliable, because the mechanical. Covering means, e.g., can become ineffective due to soiling and thus a perfect contact would exist during the charging process of the capacitor through the active energy source or prevent a conductive connection through pollution with the bullet jacket or the launch tube after the capacitor has been charged *

The object of the invention is therefore to provide such an electrical To improve igniter so that with the help of simple components a safe and with the smallest possible contact resistance Connection to be established between the capacitor and the active energy source during the charging process and a safe electrical separation of the capacitor from the other parts of the floor and thus all others the projectile jacket possibly coming into contact parts with an almost infinite contact resistance can be achieved is.

Starting from an electric detonator to trigger a Ignition pulse after a preselectable delay time with a first capacitor as energy storage, which is used to arm of the detonator from an external source of energy only for a short time connected contacts is chargeable and discharges via a delay circuit to an ignition means, this is Object according to the invention achieved in that the first

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Capacitor via at least one switching spark gap with the its charging contacts is connected.

Such a connection of at least one electrode of the Capacitor via a switching spark gap with the opposite The contact insulated from the bullet jacket is an almost ideal electrical connection between the capacitor during the charging process with the active energy source with a very low contact resistance and an almost ideal electrical separation of the capacitor from the contact, which is isolated from the bullet jacket, after switching off or loosening the connection the contacts of the projectile with those of the active energy source of the launcher can be achieved. The production and this connection is also broken without moving parts and is therefore against pollution or other possible interference, especially in military use unsusceptible.

According to a preferred embodiment of the invention, the holding spark gap is preferably one in its arc region operated glow lamp with very high ignition voltage.

By using such as a surge arrester known glow lamp as a switching spark gap is achieved that the capacitor provided in the storey as an energy store can only be charged with a very high charging voltage of e.g. 800 volts and thus everything is below the ignition voltage of the glow

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lamp of also about 800 volts lying voltages, the accidentally get to the contacts of the bullet connected to the capacitor, no accidental and therefore undesirable te charging of the capacitor can cause «By operating With such a glow lamp in its arc area, only a very small voltage drop is achieved on the glow lamp itself, so that the contact resistance of the connection during the charging process is negligibly small.

According to a further embodiment of the invention, the electrical "Igniter designed in such a way that the maximum voltage to which the first capacitor is charged is less than is the ignition voltage of the glow lamp. This maximum tension, which is applied to the capacitor after the charging process is inevitable to "the on the glow lamp during the charging process occurring voltage drop is lower than that of the active one Charging voltage delivered by the energy source. The size of this charging voltage is to be chosen so that it is only slightly larger than the ignition voltage of the glow lamp, thus due to the voltage drop occurring on the glow lamp during the charging process the voltage on the capacitor after charging is lower than that required by the glow lamp Ignition voltage is · Ignition of the glow lamp is therefore due to the pending on the capacitor after the charging process Voltage not possible.

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According to a further embodiment of the invention, the The charging voltage delivered by the external energy source is less than the ignition voltage of the glow lamp, but briefly periodically repeating voltage peaks that are greater than the ignition voltage *. By choosing one of these The charging voltage emitted by the active energy source ensures that the voltage across the capacitor after the charging process occurring maximum voltage is always lower than the ignition voltage of the glow lamp. This will definitely be a Renewed ignition of the glow lamp by the storage capacitor voltage present after the charging process in the event of an undesired external short circuit of the on the outer jacket of the Bullet out contacts prevented "

According to a further embodiment of the invention, the first capacitor can be charged from the external energy source via a charging resistor and another capacitor, see above that the voltage on the first capacitor increases gradually. Such a gradual increase in the storage capacitor occurring voltage is achieved that the first Capacitor by choosing a certain number of charging steps is charged to a predetermined, this number proportional voltage level, so one of the size of this Charging voltage proportional time delay can be set until the ignition pulse is emitted. ' .

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According to a first embodiment of the invention, the Delay circuit of the electric igniter on of a clock controlled switch.

In this first embodiment, the clockwork serving as a delay circuit can either be activated immediately upon launch of the bullet or only by one e.g. on impact of the floor triggered further switches can be started «

According to another embodiment of the invention there is the delay circuit of the electric igniter from one Another capacitor, which is operated via a switch, which is preferably actuated by the impact of the electric igniter is connected to the first capacitor and to which a discharge circuit made up of a further switching spark gap and the ignition means is connected in parallel.

All details of the invention will be explained with reference to the embodiments shown in the drawing.

Show in detail:

Figure .1 the electrical circuit of a detonator with a clockwork serving as a delay circuit,

FIG. 2 shows the electrical circuit of an igniter with one serving as a delay circuit Ignition capacitor,

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FIG. 3 shows the curve on the storage capacitor

occurring voltage with constant charging voltage, ■ --.-

Figure H shows the course of the occurring at the Spexcher capacitor Voltage at a charging voltage with pulse-shaped voltage peaks,

FIG. 5 shows the electrical circuit of an igniter for gradually charging the storage capacitor and

Figure 6 shows the course of the electrical circuit according to FIG. 5 occurring voltages.

Contacts la and Ib led out to the outer jacket of a projectile, not shown here, are connected to a capacitor 2 serving as an energy store, one electrode of capacitor 2 being connected directly to contact Ib and the other electrode of capacitor 2 via a switching spark gap / to contact la connected is. The capacitor acts on an electrically triggered ignition means U, which is connected in parallel to the capacitor 2 via a switch 5. The switch 5 is closed by a clockwork 6, not shown here, after a delay time to be set. _

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In the other embodiment shown in FIG of the electric igniter, the capacitor 2 acts via a Switch 5 and a charging resistor 7 in series with it to another serving as an ignition capacitor Capacitor 8, which in turn has a further switching spark gap 9 is connected to the ignition means U to be triggered electrically. In this embodiment of the invention, the switch 5 is preferably at the impact of the Floor closed, so that afterwards a reloading of the Capacitor 2 takes place on the ignition capacitor 8, wherein the time constant of this recharging process due to the size of the ignition capacitor 8 and the charging resistor 7 is given »If the ignition capacitor 8 is charged so far, that the ignition voltage of the switching spark gap 9 is reached, the ignition capacitor 8 discharges suddenly via the then conductive switching spark gap 9 to the electrical ignition means 4 and thus triggers an explosive charge, not shown here, for example. The delay time after which the explosive charge is released after the The projectile is ignited by dimensioning the For the reloading process decisive switching elements 7 and 8 * freely selectable.

In the embodiments shown in FIGS. 1 and 2 of the electric igniter, the charging of the capacitor 2 provided as an energy storage device is carried out,

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by making the contacts la and Ib immediately before the Projectile, e.g. via sliding contacts (not shown here) between projectile and launch tube, are connected to an active energy source 10. The one given off by the energy source The charging voltage must be at least slightly higher than the ignition voltage the contact spark gap 3 so that it is conductive will. - -

In FIG. 3, the voltage curve is that which occurs across the capacitor 2 Voltage 20 in. Is shown as a function of the charging time t, the magnitude of the ignition voltage 21 and the magnitude of the charging voltage output by the active energy source 10 is also indicated. The charging voltage 22 emitted by the energy source 10 may only be so much greater than that Ignition voltage 21 of the switching spark gap 3, that the maximum voltage 20 occurring on the capacitor 2 is due to those occurring in the transmission range of the holding spark gap 3 The voltage drop remains sufficiently below the ignition voltage 21 of the holding spark gap 3. This ensures that even with a subsequent external short circuit of the contacts la and Ib, a discharge of the capacitor 2 via the switching spark gap 3 is not possible because the ignition voltage of the holding spark gap 3 is determined by the charging voltage of the capacitor is not achieved.

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In the course of the curve on capacitor 2 shown in Fig Occurring voltage 20 is a given by the energy source 10 .Ladespannung 23 shown, in contrast to the in Fig. 3 shown charging voltage 22 is not constant, but has periodically occurring short-term voltage peaks. Only when the first voltage peak occurs the charging voltage 23 becomes the ignition voltage of the switching spark gap 3 exceeded and the charging process of capacitor 2 started. The constant portion of the charging voltage 23 the energy source 10 is still so large that the Burning voltage of the switching spark gap 3 is not fallen below, so that after the occurrence of a first voltage peak the charging process of the capacitor 2 independently of one recurrence of such a voltage spike continued will. Such a charging voltage 23 has the advantage that the voltage 20 occurring on the capacitor 2 after the charging process is in any case less than the ignition voltage 21 of the switching spark gap 3.

In the embodiment shown in Fig. 5 of the electrical With the igniter, another capacitor 11 is connected in parallel to the active energy source 10 and is charged via a charging resistor 12 Voltage 26 then reaches the contacts la and Ib of the actual electric detonator.

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As shown in more detail in Fig. 6, is due to the ^; Energy source 10 is charged the charging voltage 22 via the charging resistor 12 and only when the ignition voltage 21 of the switching spark gap 3 is reached on the capacitor does the voltage 26 on the capacitor 11 transfer to the capacitor 2 of the electric igniter. The capacitor 2 is thereby gradually transferred to its storage voltage 20 charged, the contact spark gap 3 is only conductive for brief moments, namely in.dem moment when the difference between the voltage 26 occurring on the capacitor 11 and the storage voltage 20 present on the capacitor 2 is equal to or greater than the ignition voltage 21 of the contact spark gap 3. The capacitor 11 then discharges very quickly to the capacitor 2, so that the switching spark gap 3 is extinguished again. The number of recharging processes occurring from the capacitor 11 to the capacitor 2 is a direct measure of the size of the voltage 20 present at the capacitor 2, so that the size of this voltage 20 can easily be set by a counting process.

The delay time until the triggering, which is not shown here Explosive charge by the ignition means 4 after closing of the switch 5 when the projectile hits is not only due to the size of the resistor 7 and the ignition capacitor 8, but also by the size of the pending on capacitor 2 Voltage 20 determined. By adjusting the size of this voltage applied to the capacitor 2, the Delay time for triggering the detonation after impact of the storey can be selected.

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Claims (7)

Patent claims 1. Electric igniter for triggering an ignition pulse after a preselectable delay time with a first capacitor as an energy store, which is used to arm of the detonator can be charged from an external energy source via only briefly connected contacts and itself discharges via a delay circuit to an ignition means, characterized in that the first capacitor (2) via at least one switching spark gap (3) is connected to its charging contacts (la, Ib). 2. Electric igniter according to claim 1, characterized in that g e k e η η shows that the switching spark gap (3) is a glow lamps preferably operated in their arc area * pe with a very high ignition voltage is " 3. Electric igniter according to claims 1 and 2, characterized ge k e η η ze i Ch η e t that the maximum voltage (20) to which the first capacitor (2) is charged is smaller than the ignition voltage (21) of the glow lamp (3). '. "■ - ■ - 3 0 9809/0292 - Ill - - 4. Electric igniter according to claims 1 to 3, characterized marked that by the external energy source (10) discharged charging voltage (2 3) • less than the ignition voltage (21) of the glow lamp (3) is, but has short-term, periodically repeating voltage peaks that are greater than the ignition voltage (21) are. 5. Electric igniter according to claims 1 to 4, characterized in that the first capacitor (2) can be charged from the external energy source (10) via a charging resistor (12) and a further capacitor (11) is, so that the voltage (20) on the first capacitor (2) increases gradually, 6. Electric igniter according to claims 1 to 5, characterized characterized in that the delay circuit a switch (5) controlled by a clockwork (6). 7. Electric igniter according to claims 1 to 5, characterized characterized in that the delay circuit consists of a further capacitor (8), which is preferably through the impact of the electrical Detonator operated switch (5) with the first capacitor (2) is connected to which a discharge circuit (4,9) consisting of a further holding spark gap (9) and the ignition means (4) is connected in parallel. 309809/0292 Blank page