FR2798927A1 - Active bi-mode charge for masking in radar and IR ranges comprises fibers with metallized core assembled in rounds forming a wedge(s) impregnated with pyrophoric liquid - Google Patents

Abstract

An active bi-mode charge for masking in radar and IR ranges comprises fibers with a metallized core assembled in rounds forming a wedge(s) impregnated with a pyrophoric liquid and protected from air by an envelope. An active bi-mode charge for masking in radar and IR ranges comprises fibers with a metallized core assembled in rounds forming a wedge(s) impregnated with a pyrophoric liquid and protected from air by an envelope. Independent claims are included for the production of the above product by filling the space between the fibers with pyrophoric liquid under inert gas and impregnating and protecting the product against air and a protective armament for protecting an operation platform with launching means, security devices and dispersion systems comprising the above product.

Description

The field of the present invention is that of the countermeasure for protecting a platform which is attacked by an opposing threat, for example a missile guided by a homing device or an ammunition 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 to the platform and will even lure this threat out of the way. The platform to be protected may be a land, sea or air platform.

More particularly, the present invention relates to a dual mode active load and a countermeasure ammunition for protecting a platform attacked by a threat guided by a bi-mode homing means that is operating in the field. infrared domain and in the field of radar waves (electromagnetic waves millimetric to centimetric). This type of homing device correlates the information from its infrared detector and its radar to determine if they are related to the same platform.

The infrared and radar signatures (or radar echoes) produced by the active charge of the countermeasure munition are only taken into account by the threat seeker if these signatures plausibly represent, in particular by their extent, their intensity. , their spectrum and their spatial position such a platform.

The problem is to perform a two-mode active load that fulfills these functions.

one could consider to produce this effect to use an active charge producing an infrared signature, this charge would use the combustion of pyrotechnic composition or pyrophoric product and an active charge producing a signature radar, this charge would use the dispersion of metallic or metallized fibers often designated by the expression chaffs. Such an approach supposes the realization of complex means for the deployment of the two types of active charges in space and in time. Furthermore, US Pat. No. 4,815,386 describes sponges, possibly metallic, whose cells are filled with pyrophoric powder. But this type of active load does not solve the problems mentioned above. If, for such a metal sponge there are indeed infrared and radar signatures, the radar echo is far from optimum in intensity because the characteristic dimensions of the sponge are not tuned to the wavelength of the radar, and in extent (Equivalent Surface Radar, SER) because there is no sufficient spatial dispersion of the sponge. Finally, because of its mass, the sponge filled with pyrophoric powder will have a fairly high descent speed and infrared and radar signatures will be too fleeting in the detection field of the threat seeker. The present invention relates to a bi-mode active load of a countermeasure munition for decoying in the infrared range and the radar range; said bi-mode active load essentially consists of fibers of adapted length whose core is metallized, said fibers are assembled in logs forming at least one wafer and said wafer is impregnated with a pyrophoric liquid and is protected from any contact with air through a closed and sealed envelope until functional deployment of the active load.

The countermeasure munition releases at least one such slab at a given point of space away from the platform to be protected. The protective shell of the wafer is torn and the metallized fibers are dispersed upon release active charges. The scattered metallized fibers form a cloud of electric dipoles that will reflect the radar waves emitted by the threat: the detected radar echo is even more intense than the metallized fibers have a length close to half that of the length of the radar of the threat and it is in this sense that we speak of the adapted length of metallized fibers. In addition, the number of dispersed fibers is involved in the design of the Radar Equivalent Surface. Simultaneously the pyrophoric liquid dispersed with fibers will ignite on contact with the air and produce an infrared signature which will be detected by appropriate sensor of the threat. The threat guiding device will correlate the infrared radar information given by its detectors and interpret them as corresponding to a plausible potential target and will direct the threat to that region of space. Advantageously, the pyrophoric liquid for impregnating the wafer comprises at least one pyrophoric liquid chosen from the group formed by trialkylaluminiums-triethylaluminium, trimethylaluminium-tialkybores-triethlylboron, trimethylboron, and organosilanes. The pyrophoric impregnating liquid will optionally be diluted in a solvent of these liquids and preferably this solvent will be a liquid hydrocarbon - hexane,. The selection of a single pyrophoric liquid, a mixture and / or a dilution in a solvent makes it possible to adjust the duration, the intensity and the spectrum of the infrared radiation emitted by the active charge and to size it from the point of contact. infrared view.

example we can create an intense radiation, at fairly high temperature, but of short duration to simulate an aircraft-type air platform, or low radiation, low temperature and long enough to simulate a platform land or naval. Advantageously, the core metallization of the fibers of the active charge is made with a metal that is a good conductor of electricity, this metal is chosen from the group comprising aluminum, cadmium, copper, gold, iron and nickel. platinum, rhodium, silver, tungsten, zinc, in the present application nickel is preferred. The thickness of the metallization layer will be between about 5 μm and about 25 μm and preferably between about 5 μm and <B> 10 μm. The fibers used for producing these active charges will have a core preferably of circular section. In order to have relatively light fibers in large numbers, for a given volume, the diameter of the core of the fibers will be between about 10 μm and about 200 μm and preferably between about 25 and 25 μm approximately.

In a first embodiment the metallized fiber core is a non-pyrolyzable material such as for example glass, silicon carbide, boron, glass being the preferred material. The metallized fibers are full. The impregnation of the slab by pyrophoric liquid then concerns the interstices between the fibers collected in logs the pyrophoric liquid filled these interstices.

relate to this first embodiment, the metallized fiber logs whose core is optionally pyrolyzable material but for which there has been no pyrolysis operation.

In a second embodiment, the core of the metallized fibers is made of a pyrolyzable organic material. This core is destroyed by pyrolysis: the metallized fibers are hollow and, if the pyrolysis has been complete, there remains for each fiber only a tube formed by the metallization coating. The impregnation with the pyrophoric liquid then concerns the interstices between the fibers but also hollow parts inside the fibers. The polymers yielding pyrolyzable fibers at average temperatures of about 300 to 500 C are suitable for this kind of application, the preferred material for this use is polypropylene.

The present invention also relates to a process for manufacturing the bi-mode active filler according to the invention, such as from a fiber log slab. The interstices between the fibers are filled with pyrophoric liquid by capillarity or by immersion. under the atmosphere of inert gas, the wafer thus impregnated is protected from the air. According to a variant of this process - the pyrolysable core of the metallized fibers gathered in the wafer destroyed by carrying, under hot air flow, the wafer at an elevated temperature so as to ensure the pyrolysis of the core material and avoid oxidation metal, temperature of the hot air during this operation is between about 400 C and about C.

the interstices between the fibers and the inside of the fibers are, as before, filled with capillary or dip pyrophoric liquid, this operation being carried out under an inert gas atmosphere, the wafer thus impregnated is protected from the air. This invention also relates to a countermeasurement munition for protecting a given platform, said munition comprising, in particular, launching means, safety devices and dispersion systems, and is such that it comprises at least one bi-active load. manufactured as described above. The active charges are collected in the form of a slab or even stack of slabs whose diameter is close to the caliber of the munition. The means for launching the ammunition are, for example, of the mortar type or of the solid propellant motor type. Safety devices are typical of those that usually equip countermeasure ammunition ammunition, close-impact security.

dispersing systems that can be triggered by preprogramming or by remote control making it possible, on the one hand, to tear the protective shells of the logs constituting the slabs and, on the other hand, to disperse the metallized fibers in the space.

The present invention solves the problem was to create with a single active load a two-mode effect an infrared signature and a radar signature simultaneous in time and located at the same point of space.

Metallized fibers, very small diameter are light and therefore have, once dispersed, a very low speed of descent so the radar signature will be quite long. Moreover, the combustion of the pyrophoric liquid will also produce ascending and turbulent hot air currents which will favor the flight of the cloud of fibers and also give the fibers random orientations reducing the horizontal polarization effect of conventional chaffs.

The choice of the pyrophoric impregnating liquid regulates the duration of the combustion and the radiated infrared spectrum.

Finally this bi-mode payload has a very good constructive index since virtually all its apparent volume includes elements that participate in the decoy. below the invention is explained in more detail with the aid of figures representing a particular embodiment.

Figure 1 shows schematically the longitudinal section of a metallized fiber.

Figure <B> 2 </ B> represents the view of a wafer according to the invention.

For the readability of Figure 1 the transverse dimensions of the fiber are very exaggerated compared to its length. Fiber 1 has an outer metal coating 2; the metal coating preferably nickel was achieved by an electroplating operation. Inside there is a part 3 of the polymeric core of the fiber, in this particular case the operation of pyrolysis of the core was not complete and it remains this tubular part 3. The pyrolysis operation is explained later. The hollow portion 4 of the fiber will be filled with a pyrophoric liquid as explained elsewhere.

FIG. 2 represents a pancake according to the invention. Said slab 10 has, in this embodiment, substantially the shape of a circular sector 60 opening and the thickness of this slab corresponds to the length of the metallized fibers this length being adapted, as previously defined, to the length radar wave to lure.

this figure the line in broken line 11 defines the ideal contour of the slab. The curvature of the outer portion 12 corresponds to the inner radius of the container of the payload and the curvature of the inner portion 13 corresponds to the outer radius of the dispersion device, generally an axial dispersion rod containing a pyrotechnic charge. The payload is an assembly in this case of 6 of these slabs 10 around the dispersion device, and a stack of such assemblies over the entire height of the container. In the slab 10 are bundled logs 30,31,32, a few millimeters in diameter; these logs consisting of a multitude of fibers 20 parallel to each other, these logs 30,31,32 are deformable and can be grouped to best fill the volume delimited by the pattern 11. This slab which has been impregnated by a pyrophoric liquid is protected from the air by a thin envelope but tight which is not shown here, but which corresponds approximately to the layout 11. Possibly several slabs can be stacked in the same envelope thus forming a kind of neighborhood, l assembly of several quarters around the dispersion device forming the payload, the shape of the protective envelope arranged for this configuration. For the manufacture of an active charge wafer according to the invention, one starts from a long fiber or a wire (of glass or polypropylene, for example) which is metallized by a deposition of metal, preferably of nickel. . The deposit, fairly thin 5.4m approximately lol, m approximately, is carried out in the usual manner by electroplating or any other method. The realization of an active charge wafer then comprises the following steps, the first of which are also used for the manufacture of conventional chaff charges - winding of the metallized fiber on a cylinder, on one or more layers - the fibers are then cut in a generatrix of the cylinder, they are soaked in a lubricating bath and all the fibers are wound in a tin paper to form a log, the log is cut into the desired lengths (length of fibers adapted to the length) wave of the radar to decoy), the logs thus cut have approximately icm of diameter and heights from a few millimeters to a few centimeters - the logs are gathered in slabs whose diameter is close to the caliber of the ammunition countermeasure often of 40 and Approximately 60 mm - if the metallized fibers have a polymeric core, this polymer is pyrolyzed by heating by air the slab, the chosen temperature is such that on the one hand it ensures the destruction of the polymer and on the other hand it does not oxidize the metal covering the core fiber; this temperature is preferably between about 400 ° C. and about 500 ° C. the impregnation of the wafer is then carried out by the pyrophoric liquid prepared elsewhere, the impregnation is carried out by capillarity by immersion in the pyrophoric liquid, this operation is carried out under an inert atmosphere, the metallized fibers have a non-pyrolyzable core, therefore, the impregnation with pyrophoric liquid only concerns the interstices between the fibers and the peripheresis of the wafer, if on the other hand the fibers have a pyrolyzable core which has been destroyed according to the method previously described and therefore are hollow, the Impregnation with the pyrophoric liquid will also concern the inner part of the fibers.

the wafer thus impregnated is enclosed in a tightly sealed envelope, the envelope is made of a material compatible with the pyrophoric liquid, the wafers, thus protected by their envelope, are assembled in the counter measurement munition.

Claims (1)

<B> Claims </ B> 1. Dual mode active charge, for decoying in the radar and infrared range, consisting essentially of fibers (1.20) of suitable length and whose core is metallized, said fibers being assembled in logs <B> (30 , 31,32 ...) </ B> forming at least one wafer (10) characterized in that said wafer is impregnated with a pyrophoric liquid and is protected from the air by a closed and sealed envelope. Two-mode active charge, according to the claim, characterized in that the pyrophoric liquid impregnation comprises at least one pyrophoric liquid selected from the group consisting of trialkyaluminiums, trialkylbores, organosinales. Two-mode active charge, according to the claim, characterized in that the pyrophoric liquid impregnation is diluted in a solvent. Dual-mode active charge, according to the claim, characterized in that the metallization of the fibers is made with a metal that is a good conductor of electricity. Dual-mode active charge according to Claim 4, characterized in that the thickness of this metallization layer (2) is between approximately 5 μm and approximately 25 μm. . Dual-mode active charge according to one of Claims 1 to 5, characterized in that the metallized fibers have a core (3) whose diameter is between about 10 Am and about 200 Am. 7 dual mode active charge according to claim 6 characterized in that the metallized fibers have a non-pyrolysable material and that the wafer impregnation by the pyrophoric liquid concerns in particular the interstices between the fibers. Dual-mode active charge according to claim 6, characterized in that the metallized fibers have a core of pyrolyzable material which is destroyed by pyrolysis before impregnation of the wafer with the pyrophoric liquid, the impregnation with the pyrophoric liquid concerning the interstices between the fibers and the hollow part (4) of the fibers. <B> 9 </ B> Dual mode active charge according to claim 8 characterized in that the metallized fibers a polypropylene. <B> 10. </ B> Method for manufacturing the active charge mode according to one of claims 1 to 7 characterized in - the interstices between the fibers are filled with pyrophoric liquid, this operation being done under gas atmosphere inert, the wafer thus impregnated is protected from the method of manufacturing the active load mode according to one of claims 1 to 5, 8 and 9 characterized that - the pyrolysable core of the metallized fibers is destroyed by wearing, under hot air flow, the slab at a temperature so as to ensure the pyrolysis of the core material and avoid the oxidation of the metal, - the interstices between the fibers and the inside of the fibers are filled with capillary pyrophoric liquid this operation being carried out under an atmosphere of inert gas, the wafer thus impregnated is protected from air. <B> 12. </ B> Countermeasure ammunition, to protect platform, including launching means, safety devices and dispersion systems characterized in that said munition comprises at least one active load bi -mode according to one of claims 1 to 9.