FR2930984A1 - METHOD AND AMMUNITION OF COUNTER-MEASUREMENT BY UNIDIRECTIONAL VISION SCREEN - Google Patents

Abstract

The present invention relates to a method of protecting a platform (P) attacked by an opposing threat (M), for example a homing missile or a machine guided by a firing line, this protection method comprises the deployment of at least one substance forming a screen (E) between the platform (P) and the threat (M) and is characterized in that it comprises the installation of at least one emissive element (W) between the threat (M) and the screen (E), this emissive element emitting visible radiation and / or infrared or radar.The invention also relates to the munitions implementing this method.The invention is applicable in the field of the countermeasure.

Description

The field of the present invention is that of the countermeasure. The purpose of the countermeasure is to protect a platform that is attacked by an opposing threat, for example a missile guided by a homing device or a munition directed by a firing line. The protection of the platform is often achieved by a combination of means that will prevent the device guiding the threat from directing it towards the platform and even lure this threat out of the way.

The opposing threat can be automatically directed to the platform via an infra-red or radar autodirector, or this threat can be directed to the platform by direct vision, by camera or by laser designation of the platform. form.

The platform can be land, sea or air; it can be fixed, for example a terrestrial installation, or mobile such as an armored vehicle, a ship or an aircraft.

He is known to protect a platform, attacked by a threat such as a missile, from deploying a screen between the platform and the threat. This screen acts in the visible or infrared range or that of the radar waves (millimeter to metric waves) with possible overlays of these different areas, especially for the visible and infrared. Either the radiation to be detected by the seeker of the threat is absorbed by the screen, or the radiation emitted to guide the threat is reflected by the screen and the threat no longer receives a useful signal to guide it: within the meaning of the detection in the relevant spectral domain (visible, infrared 2 2930984 or radar) the threat no longer sees the platform and can no longer move towards it.

The protective screen is deployed either by the combustion of fumigated pyrotechnic substances or by the dispersion of mineral or organic substances of a suitable nature, shape and size. The dispersion of the substances forming the screen can be done in different ways, in particular by pneumatic means or pyrotechnic means. This shield is essentially a cloud of particles and gases deployed around the platform or at a distance from it.

The efficiency of the cloud of particles forming the screen is evaluated according to the geometry of the cloud. thickness and concentration of particles and also using intrinsic coefficients to particles essentially the mass extinction coefficient of said particles.

A first problem is to always increase the efficiency of these screens to increase the confusion of the threat when the platform is hidden by the screen and the threat no longer sees this platform.

A second problem lies in the fact that if the screen masks the threat and renders inoperative the threat that no longer sees the platform; reciprocally, the threat is hidden for the platform: the platform can not attack the threat and, if it is a mobile platform, it can be embarrassed in its maneuvers to escape the threat. The present invention relates to a method of protecting a platform attacked by a threat, which method comprises the deployment of at least one substance forming a screen between the platform and the threat, characterized in that it includes the establishment of at least one emissive element between the threat and the screen. Advantageously, one of the substances deployed to form the screen is reflective for the radiation of the emissive element. The present invention also relates to an ammunition implementing this method. This ammunition can be in the form of a single object or two distinct submunitions. The present invention solves the aforementioned problems, in particular by durably dazzling the threat guiding device and thereby increasing its confusion, and also by allowing the platform to detect by contrast, through the screen, the threat to counter-attack or to move in his maneuver to escape the threat.

A detailed description of the invention is now given concerning a method of protecting a platform attacked by an opposing threat, for example a homing missile or a machine guided by a firing line, this method of protection comprises the deployment of at least one substance forming a screen between the platform and the threat and is characterized in that it comprises the establishment of at least one emissive element between the threat and the screen, this emissive element emits visible and / or infrared or radar radiation. The screen is formed around or a few tens of meters from the platform by dispersing by means of pneumatic and / or pyrotechnic substances forming a cloud of particles and gases. The substances used are, for example in the visible range and in the infrared range, metal flakes a few microns wide and a few tenths of microns thick. The particles are dispersed from pots that are ejected towards the threat by launching systems placed on or near the platform to be protected. The dispersion is during the ballistic flight of said pot or when the pot is dropped on the ground, at a predetermined distance from the platform. The emissive element is placed between the threat and the screen from a launching system that the skilled person knows how to dimension in order to obtain this disposition. This emissive element must then now be in this position for a sufficient time: either the emissive element will rest on the ground or, if it remains in the air, its fall is slowed down by appropriate devices such as for example parachutes. . It is possible to envisage a single emissive element whose operating time is long, for example from 60 to 90 seconds. One can also consider a plurality of such emissive elements to create multiple emitting sources between the threat and the screen. It is also possible to envisage several emissive elements operating in cascade, that is to say so as to have at least one emissive element in activity between the threat and the screen for a duration of 60 to 90 seconds, and even a longer duration. The emissive element placed between the threat and the screen 2930984 produces radiation, for example visible and / or infrared. Part of this radiation directly illuminates the threat, another part is diffused towards the threat by the screen, the scattered radiation is the radiation deviated by the particles forming the screen in directions different from the direction of incidence. All this radiation that illuminates the threat, on the one hand, dazzles the seeker or the shooting conduct of the threat, and on the other hand increases the contrast of the threat, that is to say increases the vision that the threat platform.

Advantageously, at least one of the substances deployed to form the screen is reflective for the radiation of the emissive element. By reflective is meant here that the substance, illuminated by incident radiation, will strongly diffuse this radiation in a direction substantially opposite to the incident direction. This effect is either obtained by the same substance as that used to form the screen, or obtained by the addition to this substance material of high diffusion power with respect to the radiation of the emissive element, the diffusion power is the ability of the substance to deflect a portion of the incident radiation in directions different from that of the incident radiation.

In a particular implementation of the method, at least one emissive element is placed in the screen, ie in the cloud of particles formed by the dispersion of the substance provided for this purpose. More precisely this emissive element is placed at the edge of this cloud, on the side of the threat. This particular arrangement of at least one emissive element 35 increases the diffusion of radiation emitted by said emissive element towards the threat. This arrangement is achieved by a suitable choice of operating parameters of the system capable of setting up the emitting elements. In this method, when the screen deployed between the platform and the threat comprises one or more absorbing substances in the visible range or the infrared, the emitting element radiates in the visible or infrared range, on the other hand if the substance forming the screen has a wider absorption spectral range that covers both the visible and the infrared range (or part of it) while the emitting element will radiate in the visible and in the infrared. Advantageously, the screen comprises at least one substance with high diffusion power in the visible or infrared range or in an expanded spectral range: visible and infrared according to whether this screen is absorbing in the visible or the infrared or in a broad spectral range that includes visible or infrared. Preferably in the process according to the invention the radiation of the emissive element is produced by the combustion of a pyrotechnic mixture. This pyrotechnic mixture comprises a binder which coats or agglomerates an oxidizing charge, at least one reducing charge such as magnesium or aluminum and optionally various known additives and in particular additives for increasing the radiation or adjusting the spectral range. This pyrotechnic mixture burns in a suitable support and its combustion is initiated by electropyromechanical means during the operating sequence of the system capable of placing the emissive elements. The present invention also relates to an ammunition for the implementation of this method. This is a countermeasure munition for protecting an attacked platform by an opposing threat, this ammunition includes a device capable of deploying at least one substance forming a screen between the platform and the threat and also includes a system adapted to place at least one emissive element between the threat and the screen. This emissive element emits a suitable radiation.

There may be a plurality of emissive elements, such as those previously mentioned, creating multiple emissive sources between the threat and the screen. It is also possible to adapt a plurality of emissive elements operating in a cascade, ie in such a way as to have at least one active emissive element permanently active between the threat and the screen for a period of 60 to 90 seconds, and even a longer duration.

Advantageously, the device capable of deploying the substance or substances for forming the screen between the platform and the threat comprises at least one reflective substance for the radiation of the emissive element. This substance may be the same as that intended to form the screen, or it may be the addition of another substance with a high diffusion power with respect to the radiation of the emissive element.

In a first embodiment, the munition comprises two distinct sub-munitions, one comprising the device capable of deploying at least one substance 2930984 forming the screen, the other the system capable of placing at least one emissive element between the threat. and the screen.

These two submunitions are implemented in a predetermined sequence. Destacking or launching means direct the two submunitions toward the threat and trigger, with appropriate delays, the device capable of forming the screen; this device deploys the substance forming the screen at the desired distance and the system able to place the emissive elements that are placed and activated between the threat and the screen. These discharging or launching means are generally pyromechanical means initiated electrically. With the aid of 15 properly timed pyrotechnic relays these means activate the device capable of forming the screen and the system capable of setting up the emitting elements.

In a second embodiment, said munition is composed of a single carrier vector comprising a device capable of deploying the substance forming the screen and a system able to place the emissive elements between the threat and the screen.

This ammunition is ejected towards the threat, for example by a pyromechanical device, from a launch tube.

In a first variant, the same disperser system triggers the device capable of deploying the substance forming the screen at the desired distance from the platform and activates the system able to place the emissive elements between the screen and the threat: the latter This phase involves the ejection of the emitting elements 35 towards their final position and also their operation. The dispersing system, generally pyrotechnic, is itself initiated by timed pyrotechnic relays, from the pyromechanical device for ejection of the carrier vector.

In a second variant the carrier vector comprises two separate dispersing systems, one activating the device capable of forming the screen and the other activating the system capable of placing the emitting elements. These dispersing devices are initiated from the pyromechanical ejection device of the carrier vector.

Below the invention is explained in more detail with the aid of figures representing a particular embodiment of the invention.

FIG. 1 represents, in schematic section, a munition according to the invention, it is here of the single carrier-vector type. FIG. 2 represents the ammunition implemented on the field of operations. According to FIG. 1, the ammunition 1 is here represented outside its launching tube. The munition 1 comprises a body 2 separated in two parts by a transverse partition 4. The munition is aerodynamically stabilized in its trajectory by fins 3 which are shown in the deployed and locked position. The rear part of the munition contains the device 5 capable of deploying a screen E. This device 2930984 comprises in particular a substance 6, preferably a mixture of substances, as previously described, and a dispersing system 10. The front part of the munition contains the system 7 capable of placing the emissive elements W. This system comprises emissive elements 8 and a dispersing device 11. The dispersing devices 10 and 11 are connected by a relay 13 and they are initiated by a suitably timed relay 12 The pyrotechnic chain constituted by the relays 12 and 13 and the dispersing devices 10 and 11 is here arranged along the axis of the munition 1.

The ammunition 1 is launched from a launch tube which also serves as a storage tube. This tube is generally arranged on the platform to be protected. The launch of this ammunition, from the launch tube, is by a pyromechanical system initiated electrically from the control station of the platform. The operation of this pyromechanical device will also initiate via the relays 12 and 13 the operation, respectively, of the device 5 capable of creating a screen E and the system 7 capable of placing the emissive elements 8. The time delay adopted for these 25 relay 12 and 13 is the one that initiates the dispersing devices 10 and 11 so that the screen E is formed and the emissive elements are placed at the desired points of the trajectory given the launches parameters including the inclination and the launch pulse of said munition.

The operation of the dispersing system 10 will deploy the substance 6 to create the screen E. The deployment may be a simple dispersion, by a dispersing device such as an explosive bar, of the substance 6 which is of the flake type. brass for example. The deployment can also be achieved by the combustion of a fumigant product, the substance 6 then comprises oxidizing and reducing charges with carbon chain products and possibly phosphorus. The operation of the dispersing device 11 will disperse the emissive elements 8. The emissive elements 10 8 are here breads of pyrotechnic substances whose combustion is triggered from the disperser system 11. The size and shape of these loaves is designed to ensure long service life from 30 s to over 90 s The pyrotechnic substance used includes, for example, phosphorus, iron oxide, or magnesium or ammonium nitrate. The loaves are hanging on devices that slow down their fall. These illuminating elements thus remaining prolonged in front of the screen E their efficiency is increased.

FIG. 2 illustrates the application of the present invention, on the operation site, to the protection of a tank P threatened, in M1, by an infantryman carrying an anti-tank weapon or, in M2, by a missile-launcher helicopter, more generally, the threat will be said to be a threat M. From a mortar placed on the tank, a 30 ammunition 1 (or a salvo of these ammunition) is ejected. This diagram shows a munition 1 on its trajectory and also the effects of a munition that worked. This last ammunition created, a few tens of meters from the tank P and in the direction of the threat M, a screen E; emissive elements W fall, slowed down by their braking system in front of or at the edge of the screen E, between this screen and the threat M. The direct radiation of these emissive elements W towards the threat M dazzles this threat, this direct radiation is schematized in FIG. 2 by arrows directed from the emissive elements W towards the threat M; the radiation reflected by the screen E also increases this dazzling effect of the threat and contributes to the confusion of the threat. As previously, the reflected radiation is schematized by the "arrows" coming from the emissive elements W and reflected on the screen E. For the sake of clarity, the devices which slow down the descent of the emissive elements W are not represented on these figures. On the other hand, the platform P, here a tank, for which the threat was also masked by the screen E, will again detect the threat M, since the latter, illuminated by the emitting elements, has its contrast increased by the radiation emitting elements W.

The screen E according to the invention is unidirectional: for the threat M it is opaque and dazzling, the threat no longer sees the platform, its target; on the other hand for the tank P it remains transparent: the tank P follows the evolutions of the threat M and can attack it effectively or to escape without exposing itself of the screen E.

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Claims (10)

Revendications1. A method of protecting a threat-attacked platform (P) (M) comprising deploying at least one screen-forming substance (E) between the platform (P) and the threat (M) characterized in this includes setting up at least one emissive element (W) between the threat (M) and the screen (E). 2. Protective method according to claim 1 characterized in that at least one of the substances deployed to form the screen (E) is reflective for the radiation of the emissive element (W). 3. Protection method according to one of the preceding claims characterized in that at least one emissive element (W) is placed in the screen (E), on the edge thereof, the side of the threat (M). 4. Protection method according to one of the preceding claims characterized in that when the screen (E) comprises absorbing substances in the visible and / or infrared, the emitting element (W) radiates in the same spectral domain. 5. Protective method according to claim 4 characterized in that at least one of the substances forming the screen (E) is reflective for the visible and / or infrared. 6. A method of protection according to claim 4 or 5 characterized in that the radiation of the emissive element (W) is produced by the combustion of a pyrotechnic mixture. 35 14 2930984 7. Ammunition (1), for protecting a platform (P) attacked by a threat (M), comprising a device adapted to deploy at least one substance (6) forming a screen (E) between the platform (P) ) and the threat (M) characterized in that the munition (1) comprises a system capable of placing at least one emissive element (8) between the threat (M) and the screen (E). 8. Munition (1) according to claim 7 characterized in that at least one of the substances (6) forming the screen (E) is reflective for the radiation of the emissive element (8). 9. Ammunition (1) according to claim 7 or 8, characterized in that it comprises two distinct sub-munitions, one comprising the device capable of deploying at least one substance (6) forming the screen (E). other comprising the system adapted to place at least one emissive element (8) between the threat (M) and the screen (E). 20 10. Ammunition, (1) according to claim 7 or 8 characterized in that it comprises a single carrier vector comprising the device capable of deploying the substance (6) forming the screen (E) and the system capable of placing 25 at least one emissive element (8) between the threat (M) and the screen (E). 3035