FR2545207A1 - Programming and energy-transfer device for weapon systems and projectile for weapon systems equipped with such a device - Google Patents

Abstract

Device for weapons systems comprising an aimable projectile-launching weapon containing a charge which can be activated in the direction of a target. The device comprises, on the projectile, an inductive receiver 10 which, after rectification, feeds a storage capacitor 12 and, by way of band-pass filters 19, programmable circuits which each correspond to a different modulating frequency band. The invention is used for selecting the type of application of the charge of shells, rockets or missiles.

Description

 The invention relates to projectile weapon systems containing an activatable charge, this expression designating here assemblies comprising at least one pointable weapon capable of launching said projectiles towards a target, and a programming device making it possible to determine a characteristics of at least the projectile immediately before firing.

The invention more particularly relates to such a programming device, as well as a programmable projectile usable in such a closed system.

 The field of application of the invention is extremely wide, both with regard to the nature of the projectile, which can in particular be a shell fired by a cannon, a rocket fired from a honeycomb or from a tube , a missile fired from a container, etc ..., that the modifiable characteristics (operation in fusing or percussive projectile, choice of the delay in activation after percussion or after the moment of the firing ...).

 At present there are weapon systems for projectile missiles comprising an activation rocket, the operating parameters of which are adjustable before launching. Shells are known in particular provided with a programmable rocket before placement of the shell in the firing chamber (altimetric or chronometric rockets for example). Also known are rockets or missiles whose operating parameters are adjustable by a wired channel. .

All of these systems have various drawbacks. They do not lend themselves well to high rates of fire. Two linkages or two separate actions are required to program the tank, then to ignite the propellant charge. There can be a sudden start even if the rocket's power source is bad. The kick start is generally easily accessible from the outside, which results in reduced safety against shocks
A device for igniting the initiation of the propellant charge by induction of alternating currents in a fine wire turn has also been described in patent N 71.40568, published under N 2.159.787, of the FRENCH STATE, but this device only substitutes for firing by percussion a firing by heating and neither allows nor provides the electric energy necessary for the subsequent operation of the isi fli to program it.

 The invention aims to provide a programming device and a projectile which can be used with such a device which meets the requirements of practice better than those previously known, in particular in that it largely eliminates the above drawbacks.

 To this end, a device, according to one aspect of the invention, for a weapon system intended for launching projectiles containing an activatable charge and making it possible to modify some of the characteristics of the projectile, such as the activation mode. of the load, includes, on the projectile, an inductive receiver tuned to a high frequency, receiver connected to a rectifier supplying electrical energy storage means and to bandpass filtering means making it possible to take information supplied by modulating the high frequency signal applied to the receiver and transmitting this information to a programmable circuit with which the projectile is provided.

 In practice, the inductive receiver may be an inductance-capacitance circuit tuned to a frequency ranging from a few kHz to several MHz, the higher frequencies lending themselves to the transmission of more information.

 In a particular embodiment of the invention; the energy storage means are constituted by a capacitor which, when it reaches a determined state of charge, causes the ignition of a primer to ignite the propellant charge.

 The bandpass filtering means will generally be designed to direct several pieces of information to different channels. Each of this information can be simply binary and correspond to the simple selection of an operating mode.

But one or more of the pieces of information can also give an indication of magnitude, such as for example the duration of the time interval which elapses between the departure of the projectile (ouia percussion) and the activation of the charge.

 In general, it will be more necessary to use, for carrying the information, an amplitude modulation of the high frequency carrier in one or more distinct modulation frequency bands, each corresponding to an item of information.

 A projectile according to another aspect of the invention, comprising an activatable charge in flight and a propellant charge and provided with adjustable means for modifying some of the characteristics of the projectile1 comprises an inductive receiver tuned in high frequencies connected to a rectifier which supplies electricity to energy storage means and to at least one bandpass filtering circuit, each circuit corresponding to a different frequency band capable of modulating the high frequency and making it possible to take information supplied by the frequency modulation corresponding and to apply it to a corresponding programmable member with which the projectile, said member or 1 tun of said members is provided, causing the activation of the charge in flight.

The intention will be better understood on reading the following description of a programming device which constitutes a particular embodiment given by way of non-limiting example. The description refers to the accompanying drawings, in which
Figure 1 is a block diagram of the part of the programming device carried by the projectile
Figure 2 is a block diagram showing a possible arrangement in the projectile and in the firing chamber of the main organs of the programming device.

 Referring to Figure 1, we will now successively describe the circuits carried by the projectile, then those carried by the weapon. The power supplies of the various circuits are not shown in this figure for simplicity.

 The input member of the part of the device carried by the projectile is constituted by an L-C 10 tuning circuit at the suitable high frequency which in general will be between a few kHz and several MHz. In the example illustrated, where the device is designed to transmit four pieces of information, the tuning frequency is advantageously of the order of I MHz. This circuit 10 supplies, on the one hand, a circuit for storing electrical energy and igniting the propellant charge, on the other hand, a circuit for programming the rocket of the projectile.

 The first circuit comprises a rectifier constituted by a diode bridge 11 which charges a polarized capacitor 12, of 10 F for example, constituting the electrical energy storage member. The voltage across the capacitor is also applied to a circuit comprising, in series, a zener diode 13 and the primer 14 for igniting the propellant charge.

 The second circuit includes a common part for transmitting the low frequency amplitude modulation signals of the carrier by means of a rectifier comprising a diode 15 whose output is decoupled by a resistor 16 and a filtering capacitor 17 and a wideband low frequency amplifier 18. It also has one channel for each possible modulation frequency. The four channels illustrated in FIG. 1, corresponding respectively to modulation frequencies in amplitude F1, F2, F3 and F4, comprise an input bandpass filter 19 which selects the frequency assigned to the chain. This filter 19 can be constituted by a simple selective switch, which puts the filter output in the air when it is not energized , connects it to ground when it is excited.

In the illustrated embodiment, the frequency F1 is assigned to the selection of the operation with a chronometric rocket and to the adjustment of the time interval between departure of the projectile and firing of the charge. The circuit comprises9 for this purpose, a counter-down counter 20. The counting input 21 is connected to the output of an AND gate 22, one input of which receives the output signal from the complemented filter 19 (so that the gate 22 does not is released only when the filter 19 is energized), on the other hand, the output of a shaping circuit 23, which can be a simple monostable. The down counting input 24 is connected to an AND gate 25 whose unlocking input is connected to a source of logic activation level by a contact 26 which closes definitively during the acceleration which accompanies the firing of the propellant charge (inertial contact for example). The second input of the AND gate 25 is connected to a clock 27. The frequency of the clock 27 will generally be much lower than the frequency F1, which must be high to reduce the programming time. In practice, it suffices a clock frequency of 100 Hz, which gives an accuracy of 1/100 over a travel time of 10 s and corresponds to a maximum error of 6 m for a speed of 60o m / s
Finally, the up-down counter 20 is provided with a zero decoder which provides an activation signal on an output 28 to cause the ignition of the activatable load, as will be seen below.

The frequency F2 is assigned to the selection of "instantaneous firing on percussion": the corresponding filter 19 is connected to a storage device, such as a flip-flop 29, the output signal of which is applied to an input of unlocking of an AND gate 30 which receives, on another input, the zero decoding signal. Rocker 29 thus blocks the door
AND when excited. The percussion activation circuit also includes a contact 31 which closes on impact and then applies an activation signal to a second AND gate 32 whose output is connected, via an OR gate 33 , at the control input of the firing system 34.

 The frequency F3 is assigned to the selection "firing delayed by a delay # after percussion" The corresponding filter 19 is connected to a flip-flop 35 similar to flip-flop 29.

The output of the latter attacks the AND gate inputs 30 and 32 blocking these doors when the frequency F3 is received.

In this case, the gate 32 cannot transmit an activation signal when the contact 310 closes. However, the latter is connected to an input of the OR circuit 33 by a delay circuit 36, causing the activation with a determined delay # . It should be noted that if none of the frequencies Fi a F3 is present, there will be activation with a delay #, the presence of F3 having the result only of inhibiting the other activation circuits if by mistake there is also had programming using F1 and / or F2.

Finally, the device in FIG. T comprises a channel using the frequency Fis, the filter 19 of which attacks the reset input 37 of the up-down counter 20 and the reset inputs of the memories 29 and 35, which allows any time before the projectile's departure to "deprogram" and then
"reprogram" this one, that is to say to modify the conditions for igniting the initiation of the activatable charge.

 The firing circuit 34 is associated with the primer 38 and a safety contact 39 short-circuiting the primer and opening at the start of the projectile, and a safety contact 39a closing at the opening of 39 and connecting 33 and 34. Other members, for example those provided in particular for supplying the various voltages necessary from the rectifier 11 and for keeping the rockers 29 and 35 in the state where they provide an unlocking signal for the doors 30 and 32 until 'for programming, have not been shown for simplicity.

The part of the device carried by the weapon comprises a tuned circuit 40 placed so as to be coupled to circuit 10 when the projectile is at a firing station. This circuit 40 is excited by the high frequency coming from an oscillator 41 and possibly modulated by a modulator 42. To this are associated four generators 43, 44, 45 and 46 of frequency F11
F2, F3 and F4. In principle, only one of the generators is activated to program the projectile. In the case of generators 44 and 45 which provide only a selection binary ziformation, the modulation can be permanent In the case of generator 43, which provides an indication of size, an adjusting member 87 is provided to adjust the modulation time and the start of the latter is controlled by the station coming from the projectile using a contact not shown.

 We find in Figure 2 the relative disposition of the components illustrated in Figure 1. The tuning circuit 40 is molded in an insulating part 48 embedded in the rear wall 49 of the shooting chamber and connects to an electronic boot 50 combining the components 41 to 47. The rear part of the projectile, containing the propellant charge, contains the induced tuned circuit 10 and the rectifier as well as the zener diode 13 and the primer 14. The programming electronics 51 and the storage capacitor, the contacts of departure 26 and 39, the percussion contact 31 and the ignition 34 are on the contrary placed in the nose of the projectile and connected to the other part by destructible conductors at the start of the shot.

 The operation of the device emerging from the above description, it will only be briefly indicated, assuming that an activation is chosen after a given flight time, 5 s for example. Generators 44, 45 and 46 are blocked and generator 43 is then adjusted using manual control 47 to load the number 500 into the counter. This command can for example adjust the duration of the modulation (5 ms for example if F1 = 100 kHz) or stop the modulation after 500 alternations of F1.

The coming to station of the projectile 52 causes the modulation of the high frequency for a determined duration (its emission can be permanent or also triggered). The counter 20 charges at 500 (the counter obviously having to have sufficient capacity, 10 binary positions if the maximum programmable duration is 10 s). after setting the counter Q which inter comes in a maximum of 5 ms if the frequency F1 is 20 kHz), the voltage across the terminals of the capacitor 12 continues to rise. When it reaches the value corresponding to the ignition of the diode
Zener 13 (in 7 ms for 100 V for example), this one passes through the primer 14 a firing current of the propellant charge.

 The acceleration of the projectile closes the contact 26 and opens the contact 39. The door 25 being unlocked by the closing of the contact 26, the counter counts down to 100 Hz. After 5 s, the decoder provides, on the output 28, a signal which is sent to the AND gate 30. The other inputs being connected to the then active outputs of flip-flops 29 and 35, the AND gate excites, through the OR gate 33, the firing 34.

 If there is a fire stop while a programmed projectile is in position, it is enough to unlock the generator 46 to deprogram. As soon as the capacitor 12 has discharged on itself and the leakage resistors, the projectile can be reprogrammed without risk. In any case, in the event of premature departure, there is activation on percussion with a delay.

 The invention is obviously susceptible of numerous variants. In particular, it may be provided, in addition to an activation path on impact, a path selected at the same time and causing the explosion at the end of a determined period as self-destruction security, an activation channel at a determined altitude, etc. Some of the channels can be provided to have priority, that is to say that their activation makes others inoperative, or the channels can be independent. It should be understood that these variants, as well as all those remaining within the framework of equivalences, are covered by this patent.

Claims (10)

 1. Energy programming and transfer device for a weapon system intended to launch projectiles containing an activatable charge and making it possible to modify certain characteristics of the projectile, such as the activation mode of a charge, characterized in that it comprises, on the weapon, an inductor capable of providing a high frequency carrier modulated in at least one frequency band and on the projectile, an inductive receiver tuned on said high frequency, connected to storage means electrical energy and to bandpass filtering means corresponding to the on band to the frequency bands and to transmit each corresponding information to a programmable circuit with which the projectile is provided.  2. Device according to claim 1, characterized in that the inductive receiver is an inductance-capacitance circuit tuned on a frequency between a few kHz and several Ni.  3. Device according to claim 1 or 2, characterized in that the energy storage means consist of a capacitor supplied by the receiver through a rectifier.  4. Device according to claim 3, characterized by means for activating an initiation of firing of the propellant charge of the projectile when the capacitor reaches a determined charge.  5. Device according to any one of the preceding claims, characterized in that the carrier is amplitude modulated.  6. Device according to any one of the preceding claims, characterized in that several bandpass filters are provided corresponding to different bands and to binary information or of different magnitude  7. Device according to claim 6, characterized in that one of the filters is associated with a channel deprogramming channel corresponding to all the other filters  8. Device according to claim 6 or 7, characterized in that the channel or each channel corresponding to a quantity information comprises a counter-of-counter whose counting input is connected to a clock by the intermediary of sensitive means at the start of the projectile  9. Device according to any one of the preceding claims, characterized in that the inductor circuit carried by the weapon is associated with a modulator connected to a high carrier frequency generator and to controlled generators capable of supplying information in the said band or bands. frequency.  10. Device according to any one of the preceding claims. characterized in that said inductor circuit is constituted by a matched inductance-capacitance circuit placed in an insulating part embedded in the wall of the firing chamber of the weapon.  Projectile usable in a weapon system provided with a programming device, comprising an activatable charge and provided with adjustable means for modifying some of the characteristics of the projectile, characterized in that includes an inductive receiver tuned in high frequency, connected to a rectifier which supplies electricity to energy storage means and to at least one bandpass filtering circuit, each circuit corresponding to a different frequency band capable of modulating the high frequency and making it possible to take information supplied by the modulation at the corresponding frequency and to apply it to a corresponding programmable member with which the projectile is provided, said member or one of said members causing activation of the charge.  12 Projectile according to claim 11, characterized in that the inductive receiver and the rectifier are incorporated in the propellant charge and in that the energy storage means, the on said organs, and the filtering circuit or circuits are incorporated into the load that can be activated in flight.  13 Projectile according to claim 11 or 12, characterized in that means for igniting the propellant charge are incorporated into said charge and comprise means, such as a Zener diode, for controlling the ignition when the voltage at energy storage means reaches a predetermined value.