EP1288609A1 - Electrical fuze device for an ammunition body with a target sensor - Google Patents

Abstract

The ammunition fuse has a detector circuit (ZD) separating the target sensor (H) from the ignition circuit (S, DET) with safety period set by holding switch (K) closed before start current (i) and ignition controlled by comparison ( and ) of time intervals (VG, VS).

Description

The present invention relates to a device according to the preamble of claim 1 and a method to operate the device.

Bullets, bombs, etc. have been used for many years Impact fuses used by a so-called Double hood can be initiated. Double hoods exist from a ductile form, usually from sheet metal, which is double is executed and both of which are usually arranged concentrically Parts are spaced from each other. In the simplest Case there is an air gap between the two parts from a few tenths to 2 mm. The two parts are used for Impact at the finish as a switch contact for the detonator.

Depending on the design of the double hood and the Isolation of the switching points serving dielectrics varies the capacity of the arrangement within large limits. in the practical use of such ammunition always arise again unexploded ordnance, which is due to contact problems between the Switch points are attributable, and / or their evaluation circuit is not sensitive enough to initiate of the detonator.

It is therefore an object of the invention to provide an arrangement create the functional reliability of any Target sensors increased and a safe switching function guaranteed, even if this over a longer period are stored away and, for example, the presumptive Switching points have already formed oxide layers.

In addition, the control downstream of the hood should a deformed or shot before the ammunition is fired detect short-circuited hood and premature ignition, for example in the gun barrel, prevent it safely.

The control downstream of the hood should be for any Double hoods can be used and all known interference situations resist, i.e. it is not meant to be common EMR, ESD and / or EMP measures react.

Overall, the detection reliability in the event of an impact ignition is said to be can be increased with simple technical means.

This object is solved by the features of claim 1.

With an arrangement constructed in this way, it can be advantageous Way a robust target sensor and in particular achieve a low sensitivity to interference. Through the im Claim called separation of the two functions Target detection and safe processing of the ignition signal results a significant increase in system security. This allows the design of the arrangement and its sensitivity can be freely chosen.

Further advantageous refinements of the subject matter of the invention are specified in dependent claims.

Embodiment according to claim 2 can be realized very easily.

The network according to claim 3 results - by itself known dimensioning - the effect of a filter for too expected interference frequencies, such as those at launch and in Flight of the ammunition can arise. In simple In this case, a capacitor or a resistor is sufficient; it can but also one as a blocking filter against electromagnetic interference effective network.

The targeted increase in the capacity of the double hood, claim 4, reduces the influence of noise and increases thus system security.

The operating method according to claim 5 prevents premature Ignitions and serves, in addition to known mechanical Pre-pipe protection, the prevention of accidents in the vicinity of a gun.

The controlled inclusion of a start signal in the functional sequence prevents premature triggering of the ignition device; Claim 6.

The invention is illustrated below with reference to drawings explained in more detail.

Fig. 1

ein Prinzipschaltbild der Erfindung,

Fig. 2a, 2b

die zeitlichen Verhältnisse, bei einer Aktivierung des Zielsensors,

Fig. 3

eine Schaltungsanordnung zur Erhöhung der Funktionssicherheit eines Zielsensors und

Fig. 4

eine Schaltungsanordnung zur Detektion eines defekten Zielsensors.

Show it:

Fig. 1

1 shows a basic circuit diagram of the invention,

2a, 2b

the time relationships when the target sensor is activated,

Fig. 3

a circuit arrangement for increasing the functional reliability of a target sensor and

Fig. 4

a circuit arrangement for detecting a defective target sensor.

1 is a target sensor in the form of a notoriously known double hood - represented by a Switch H - present. In the normal state it works Double hood H as an open switch. When the bullet hits the switch is closed on the target. In the open Condition, the double hood H has a resistance of much larger than 1 MΩ; is in the closed state Resistance typically less than 5 Ω. Depending on the embodiment and the operating status of such a hood Capacitor with a capacitance from 10 pF to approx 1 nF. The double hood is connected via inputs E1 and E2 a control circuit ST for controlling the ignition connected to the floor. The control circuit ST controls a switch S, which in the closed state Detonator DET (primer / squib) of the projectile with an energy source U 'connects to this for ignition to supply the necessary energy.

A capacitor C is inserted parallel to the double hood H, which is an increase in the initiation energy for the control circuit ST causes and in addition to a lower one Interference sensitivity of the arrangement contributes. The Capacitance of the capacitor C can be chosen within wide limits and thus enables optimal adaptation to following circuit arrangements.

The control circuit ST consists of a detection circuit ZD, when the bullet hits the target emits a signal 01. The control circuit also contains ST a pulse circuit SH, the output of which is a switch K controls. The switch K is normally closed and causes in this state at output 01 of the detection circuit ZD a short circuit against the GND ground Power. When one arrives the shot of the projectile triggering start signal i at its input E3 gives the pulse circuit SH a signal 02 which switches K opens, causing the short circuit at the output of the detection circuit ZD is canceled.

Short-circuiting the output of the detection circuit ZD until a pulse i arrives at input E3 of the pulse circuit SH prevents the delivery of an ignition signal to a switch S. An unwanted ignition will also prevented if the double hood H in a faulty way should be closed before the launch.

The output of the detection circuit ZD is on an AND link & led, the output of the switch S acts, the ignition of the detonator in the closed state DET causes. A second input of the AND link is connected to an output 04 of a timing element VG, which, after the double hood H has been closed, is activated of the switch S during a predetermined time window releases. A third input of the AND link is connected to the output 03 of a timer VS.

After this, specified by the timing elements VG or VS Delay, the switch S is blocked or. Approved.

As shown in Fig. 1, the two known functions the double hood - namely a sensor for the detection of the impact on the one hand and trigger for the energy supply to the Detonator on the other hand - strictly separated from one another. Thereby is the sensitivity of the sensor in a simple manner against interference signals and thus the reliability detection increased.

By dimensioning the capacitor accordingly C, a capacitance of 1 µF is characteristic the sensitivity of the detection circuit ZD to the given Adjust conditions.

The illustration in FIG. 2a shows the time sequence for the regular launch and flight phase of an ammunition body. The time t ₀ is the time when an ammunition is fired.

When a bullet is fired upon arrival Start signal i begins an electrically controlled Front pipe safety interval VR of the duration Δt of typically 100 ms.

After the interval .DELTA.t, a time window .DELTA.t _{A is} generated by the impact A of the double hood H in which the ignition process can be triggered.

A time window Δt _B is shown in FIG. 2b, which arises, for example, from a premature impact B of the ammunition body on the ground (ground impact).

The time windows .DELTA.t _A and .DELTA.t _B are selected so that a reliable ignition process is possible, even when using relatively slow detonators, and is 10 ms in the exemplary embodiment.

In the event that the double hood H is damaged or short-circuited an ignition is impossible, as will be shown later.

3 is a specific embodiment for the detection circuit ZD shown. The double hood H is over the to her capacitor C connected in parallel to inputs E1 and E2 guided.

E1 is through a resistor R1 with a connector VCC connected; Resistors R2 and R5 are inverting Input of an operational amplifier V1 upstream. Between the resistors R2 and R5 are a Zener diode Z1 and a resistor R4 connected and connected to the connector GND connected. The non-inverting input of the operational amplifier V1 is on the one hand via a resistor R9 with its output and additionally via a resistor R8 with the center tap one formed from resistors R6 and R7 and arranged between the terminals VCC and GND Voltage divider connected. Parallel to the resistance A capacitor C2 is provided at R7. The output signal of the operational amplifier V1 is connected via a resistor R10 removed and as the control signal 01 the ignition of the detonator DET triggering electronic switch S, Fig. 1, fed. When switch S is closed, the detonator is activated DET ignited.

The VCC connection leads the supply voltage to the supply the electronics of the detonator.

The detection circuit ZD according to FIG. 3 has the one hand Task to detect the closing of the double hood and to generate a signal 01 at its output. on the other hand it takes over through capacitor C the one already mentioned Protection against unwanted interference.

The functioning of the detection circuit ZD is as follows: When the supply voltage VCC is built up, the capacitor C charged through resistor R1. The resistors R2 and R5 form a T filter with the Zener diode Z1, which acts as ESD protection (ESD = electrostatic discharge) is used. The resistance R4 is used to discharge the capacitor C in the stored Condition, i.e. this makes energy-free storage of the floor guaranteed. The one through the resistors R6, Voltage divider formed by R7 determines the potential at non-inverting input of operational amplifier V1. The capacitor C2 brakes the voltage rise on the non-inverting Input of the one that acts as a Schmitt trigger Operational amplifier V1 such that when the supply voltage is built up VCC the output of the Schmitt trigger is always in is in a defined state. The resistors R8 and R9 form a Schmitt trigger with the operational amplifier V1 and optimize its switching behavior.

4 is a concrete embodiment of the pulse circuit SH shown. The one working according to the "sample and hold" principle Circuit generated in the event of a defective double hood - especially in the event of an electrical short circuit between the two parts of the double hood - a signal that one prevents unwanted premature ignition of the projectile. Their inputs E2 and E3 are not shown Fixed circuit in the launcher connected a certain time (e.g. 20ms) before Firing the projectile gives an impulse i. Furthermore is the input E3 via resistors R11, R13 and a diode D11 with the non-inverting input of an operational amplifier V2 connected. Between the resistors R11 and R13 is a resistor R12 and a capacitor in parallel C11 arranged, both with the GND connection of the Power supply are connected. Between the resistance R13 and the diode D11, a Zener diode Z11 is connected and also connected to the GND connector. Between the Diode D11 and the non-inverting input of the Operational amplifier V2 is a resistor R14 and a capacitor C12 arranged in parallel, both with are connected to the GND connection. The inverting input of the operational amplifier V2 is with a reference potential REF applied.

The output signal 02 of the operational amplifier V2 becomes Control of the switch K, Fig. 1, used. It prevents that the detonator DET prematurely if the double hood is defective is ignited.

The operation of the SH pulse circuit is as follows: That through the resistors R11, R13 with the capacitor C11 T filter formed serves as EMC input protection (EMC = Electromagnetic compatibility). The resistor R13 forms an ESD input protection with the Zener diode Z11. The Diode D11 prevents the discharge of capacitor C12. Resistor R14 is used to discharge the capacitor C12 when the bullet is stored. after the Supply voltage VCC is established, the input Pulse circuit SH during 20 ms before the launch of the Geschosses a start signal i applied, whereby the Capacitor C12 is charged; it is energy storage for the "sample and hold" function.

The operational amplifier V2 forms an impedance Decoupling of the capacitor C12 from the rest of the circuit arrangement. In practice, the output of the operational amplifier takes over V2 (operated as an open drain) the function of the switch K and has the task of output 01 the Detection circuit ZD, cf. Fig. 2 as long to be short-circuited until the input E3 of the pulse circuit SH the start signal i is present.

Specifically - if the double hood H before the shot is closed - a charge of the supply voltage VCC prevented by the output of the detection circuit ZD through resistor R10 through output 01 of the pulse circuit SH switched to the potential GND and the power supply VCC is thereby short-circuited. So that is the system is finally shut down. After putting on of the start signal i is the output 02 of the operational amplifier V2, Fig. 3, high impedance.

The ignition device described is extremely suitable also for multiple loads, especially multiple hollow charges. Here, between identical ignition devices Time delay elements connected, which the necessary delays caused by dynamic processes between generate the charges and thereby sequential ignition trigger.

Of course, a double hood can also be modern Proximity and or impact detonators are replaced, whereby only minor adjustments are necessary for this, since the input impedance the ignition device is not critical. various Impedances and signal forms can be easily adjusted adapt the circuit arrangement described.

Claims (6)

Electrical ignition device for an ammunition body with a target sensor, consisting of a switch that supplies an energy source via an electronic circuit arrangement that monitors the ignition over time to an electrical ignition element with a connected ignition chain, characterized in that the target sensor (H) uses a detection circuit (ZD) from the ignition circuit (S, DET) is separated. Device according to claim 1, characterized in that the detection circuit (ZD) has an operational amplifier (V1) as an impedance converter (ZD). Apparatus according to claim 1 or 2, characterized in that a network consisting of at least one capacitor and / or resistor is connected upstream at the input of the detection circuit (ZD). Device according to one of claims 1 to 3, characterized in that the target sensor (H) is a double hood and that at the input of the detection circuit (ZD) a capacitor (C) is inserted parallel to the double hood (H). Method for operating an ignition device according to one of claims 1 to 4, with a target sensor, consisting of a switch that supplies an energy source via an electronic circuit arrangement that monitors the ignition over time, an electrical ignition element with a connected ignition chain, and one that monitors the progress of the ignition process further circuit arrangement, characterized in that a processed signal (01) of the target sensor (H) is released for signal processing during a time interval (Δt _A ; Δt _B ) if this arrives after the end of a fore-pipe safety interval (Δt) that the signal ( 01) is blocked, however, if it arrives before the fore-pipe safety interval (Δt) has expired. Method for operating an ignition device according to one of claims 1 to 4, with a target sensor, consisting of a switch that supplies an energy source via an electronic circuit arrangement that monitors the ignition over time to an electrical ignition element with a connected ignition chain, and with a further one that monitors the progress of the ignition process Circuit arrangement, characterized in that a start signal ( i ) which triggers the firing of the ammunition body is applied to the input (E3) of a pulse circuit (SH), that this is temporarily stored in the monitoring circuit arrangement, and that during this storage time the target sensor (H) is in its Function is released.

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