FR2708728A1 - Neutralising device for aircraft - Google Patents

Abstract

In a plane P intersected by the trajectory 2 of a helicopter 1, an array of ropes 6 has been erected starting from a deployment unit, each rope being attached to an explosive charge.

Description

 The present invention relates to a device for neutralizing a helicopter flying at low altitude and more generally a rotary wing or slow flight aircraft.

 Several methods are known for intercepting aircraft. Among these, anti-aircraft defense may be cited either from gun batteries, or from surface-to-air missiles or the like. These methods use heavy and expensive means and are relatively ill-suited to aircraft traveling at low altitude.

 The invention provides a low-cost anti-helicopter weapon system, simple, easy to implement, with automatic triggering and operating in a manner similar to a mine.

 More specifically, it is a device for neutralizing a helicopter in flight comprising a means of detecting its trajectory associated with a weapon system which comprises a plurality of wires and means for deploying these wires in a sheet coming from in intersection with the helicopter's trajectory, activated in response to the detection means, each wire being associated with an explosive charge comprising means for triggering its explosion in response to a voltage in at least one of the wires greater than one threshold determined.

 In one embodiment of the invention, the means for deploying the layer of wires use at least two divergent tubes contained in a substantially vertical plane, pointed towards the sky for guiding at least two propellants to which the wires are coupled , each of the wires being, by its other end connected to the explosive charge.

 In a first variant, the propellants are connected to the wires of the sheet to be deployed by means of a link which joins them together and to which the wires are harnessed.

 In a second variant, each wire of the web to be deployed is coupled to an individual propellant from its own launch tube.

 Advantageously, the explosive charge, the wires to be deployed, the launching tubes and the propellants are grouped in a mobile unit comprising means of connection with control means associated with the detection means.

 This unit can finally be equipped with means for its transport and its installation on a site.

 Other characteristics and advantages will emerge from the description below of an embodiment of the invention.

Reference will be made to the accompanying drawings, among which
FIG. 1 is a general diagram of the device according to the invention,
FIG. 2 illustrates a first alternative embodiment of the means for implementing the explosive charge,
FIG. 3 illustrates a second alternative embodiment of these means,
- Figure 4 illustrates the state of the device at the time of the capture of a helicopter.

 What presided over the conception of the invention was the search for a weapon system, to neutralize a helicopter with a mode of operation analogous to that of a land or underwater mine. In other words, an attempt has been made to implement a passive system, the triggering of which results only from the presence, in a determined zone, of the object to be destroyed. In the case of land or sea objects, the trigger results from the contact of this object with respect to the mine. This is not possible for a flying object, the inventor proposes the implementation of a "link" material between the object and the "mine" which will establish this physical contact between the object and the mine.

 In FIG. 1, a helicopter 1 and its trajectory 2 have been represented. By means of a surveillance system 3 (for example a radar) associated with calculation means not shown, the presence of helicopter 1 is detected and the direction of its trajectory 2 determined so that it is known that this trajectory will cut a substantially vertical surface (here a plane P) at an altitude compatible with the performance of the weapon system of the invention.

 This plan P is that of the deployment of a layer of wires, ropes, cables from a deployment battery 4 in response to a control signal coming from a control unit 5 itself associated with the monitoring system 3 .

 The control unit 5 can be manual or automatic. The connection between the unit 5 and the battery 4 can be carried out by any known means (conducting wires, Hertzian or infrared waves, etc.).

 As shown in FIG. 1, the detection 3 and control 5 devices are clearly distinct from the battery 4 which alone is consumable material. In addition, as will be seen below, the battery 4 will preferably be mobile or displaceable while the members 3 and 5 can be fixed.

 The deployment battery 4 comprises means so that the ropes, wires or cables are placed in the plane P so as to form a series of divergent lines 6 from the battery 4. The maximum distance d of the lines 6 in the plane P, c '' i.e. that measured at the maximum interception altitude, which results from the performance of the device fixed by construction, will be less than the diameter D of the disc swept by the rotating blades of the helicopter I. In this way, one is certain that one of these straight lines 6 will be cut by the blades of the helicopter.

 In Figure 2, there is shown schematically an embodiment of the battery 4 of the deployment means of the ropes. I1 is a box 7 equipped with a plurality of tubes or launching ramps 8 arranged in a fan, angle A of about 60 in a vertical plane.

 Each tube contains a propellant 9 shown here in the form of a small powder rocket. A rope 10 connects each propellant 9 to an explosive charge il to which it is firmly attached. The box 7 also includes a device 12, 13 for simultaneously firing the propellants 9, connected by a wire 14 for transmitting the control signal from the control unit 5.

 In FIG. 3, the variant embodiment of the rope deployment battery comprises a box 15 provided with two launching tubes 16 divergent about 600 in a vertical plane in which two propellant rockets 17 are placed on standby. These rockets are connected to each other by a cable 18 which constitutes the means for connecting the thrusters with a plurality of cables 19 attached to this cable by one of their ends and to the explosive charge 11. In this case, the cables 19 are pulled by the cable 18 and deploy as a fan between the two trajectories of the rockets 17. It is possible to use several cables such as that 18 to produce with the ropes 19 a wide mesh net.

 The cable 18 acts as a distance limiter for the cables 19 deployed, which makes it possible to control the distance d.

 Of course, in each of these variants, the ropes are washed carefully so that their deployment takes place correctly when the launchers leave. It will also be noted that the cover of the box forming the chassis of the battery of FIG. 3 is in several ejectable pieces so as to allow the correct deployment of the cables connected to the cable 18 and that the tubes 16 rather form launching ramps open laterally for allow the passage of the cable 18. In this FIG. 3, it will also be noted the presence of a device 20 for igniting the thrusters here connected by radio to the control station 5 by means of an antenna 21. Finally, the battery of Figure 3 is mounted on a platform 22 provided with wheels 23 to facilitate its movement.

 The operation of the device is as follows.

When, after detection of the helicopter by the monitoring system 3, it is foreseeable that its trajectory 2 will intersect the plane P, an order to fire the thrusters 9 or 17 of the battery 4 is given by the control station 5 . The ropes 10 or 19 are deployed in the plane P along the straight lines 6 at an instant such that a screen is formed in front of the helicopter and close enough to it so that it no longer has the possibility of to avoid.

 The helicopter therefore crosses the plane P provided with its deployed ropes and by its blades or another part of its cabin catches at least one of the deployed ropes 10 or 19. There is then a violent shock on this rope which is driven and which on the one hand carries with it the explosive charge It (with all or part of the battery case 4) and on the other hand triggers the setting system fire of this charge. This situation is shown in Figure 4 where we find most of the elements already described with the same references. If the rope is hooked by the blades of the helicopter, it constitutes by itself a first means of damaging the aircraft. In addition, it becomes entangled on the rotor which has the effect of towing the load in the vicinity of the helicopter, which will be all the more effective at the time of the explosion (expected with a certain delay). In addition, the hanging rope will have a whip effect which will probably propel the load in the direction of the helicopter.

 It is not outside the scope of the invention to provide an explosive charge per cable. Furthermore, in a more elaborate device, the load could be coupled to the rope by means of a device making it possible to hoist it along a rope in which the helicopter was caught (winch or part " swallowing "the rope and implemented at the time of the shaking).

 Finally, it will be mentioned, by way of indication, that the surface of the sheet in the plane P will preferably be an equilateral triangle of approximately 150-200 meters on a side.

Claims (6)

 1. Device for neutralizing a helicopter (1) in flight comprising means for detecting (3) its trajectory (2) associated with a weapon system, characterized in that it comprises a plurality of ropes (10, 19) and means (4) for deploying these ropes in sheet form (6), in a surface (P) cut by the path (2) of the helicopter (1), activated in response to the detection means (3), each cable (10, 19) being associated with an explosive charge (11) comprising means for triggering its explosion in response to a voltage in at least one of the cables (10, 19) greater than a determined threshold.  2. Device according to claim 1, characterized in that the deployment means (4) comprise at least two ramps (8, 16) divergent in a vertical plane each containing a propellant (9, 17) connected to the plurality of ropes ( 10, 19).  3. Device according to claim 2, characterized in that it comprises a ramp (8) and a propellant (9) by rope.  4. Device according to claim 2, characterized in that it comprises two ramps (16) and two propellants (17) connected to the plurality of cables (19) by a cable extending between the two propellants.  5. Device according to one of the preceding claims, characterized in that the load (11), the ramps (8, 16), the propellants (9, 17) and the ropes are contained in a movable unit include means (14 , 20, 21) for connection with a control station (5) associated with the detection means (3).  6. Device according to claim 5, characterized in that the movable unit is integral with a rolling platform (22, 23).