FR2716258A1 - Aircraft-launched pyrotechnic decoy flare - Google Patents

Abstract

An aircraft-launched pyrotechnic flare is provided for luring incoming missiles with advanced seeker systems away from the aircraft exhaust comprising a pellet of a gassy IR emitting pyrotechnic compsn. configured within a cavity extending symmetrically along a fore and aft axis of the pellet. The cavity is vented at the rearward surface of the pellet and a casing which covers the external surface of the pellet forward of the pellet rearward surface; the casing being strong enough to remain intact throughout the pellet combustion. Also claimed is the pyrotechnic flare.

Description

 The present invention relates to a pyrotechnic flare forming a decoy, and it relates to a particular such an illuminating decoy or flare which can be launched from an aircraft to attract approaching vehicles and are provided with advanced infrared research systems, in order that these devices move away from the exhaust of the aircraft.

 Known flare compositions contain mixtures of magnesium and polytetrafluoroethylene compressed in block form. A block is launched from an aircraft when the approach of a craft is detected. The block is ignited during launch and burns, creating an infrared source more intense than the exhaust of the aircraft. If the approaching object has an infrared finder system, it can be attracted at a distance from the exhaust of the aircraft towards the block which burns more intensely and which deviates quickly from the aircraft in falling.

 Several types of advanced infrared search systems are used in aircraft fighters to recognize and ignore the characteristics of a flare. Such an infrared finder system is sensitive to a sudden increase in the intensity of the infrared signal near the exhaust of the aircraft, produced during the lighting of a flare. When the infrared finder system detects a sudden increase in the output infrared intensity, it activates its compensation circuit for a short time so that the finder system memorizes the original trajectory and continues to follow it (i.e. that it follows the trajectory calculated by the search system from the position and the speed of the aircraft exhaust system so that it comes to strike it) ignoring all the infrared sources. This short time, for example around 0.2 s, is chosen so that, when the compensation circuit is deactivated, a conventional flare is outside the field of vision of the search system and thus the only infrared source recognized by the Finder system is the exhaust of the aircraft. Thus, the machine continues to follow the exhaust of the aircraft. Another infrared finder system is sensitive to the speed at which the flare separates from the aircraft. When a conventional flare is launched from the aircraft, it exhibits rapid deceleration and falls under the action of gravity forces so that it quickly separates from the aircraft. When the infrared finder system detects a second infrared source, it measures the separation speed of the two sources and memorizes its original trajectory and continues to follow it. If the separation speed exceeds a predetermined level, the search system ignores the second source and continues to follow the aircraft's escape. The finder system takes approximately 0.2 s to measure the separation speed. Other sophisticated infrared research systems use a combination of the two systems described above. Obviously, if an infrared flare is to be an effective decoy, it must deceive all types of sophisticated research systems.

 A known method for deceiving a whole range of sophisticated research systems comprises launching and successively lighting several flares from the aircraft, with simultaneous maneuvering of the aircraft so that it deviates from the trajectory of the craft. The principle implemented is that, when the search system successively detects and analyzes all the flares, it continues to follow its original memorized trajectory so that, at the moment when the last flare has finished burning, the aircraft has to maneuver in such a way that the exhaust pipes of the aircraft are turned away from the craft and the search system no longer recognizes the aircraft as a target. One drawback of this method is that the aircraft must carry a large number of flares which occupy a large space in the aircraft. Another disadvantage is that the aircraft must deviate from the trajectory of the craft while maneuvering and therefore cannot follow the most direct route out of a hostile region.

 The object of the present invention is to remedy certain of the aforementioned drawbacks at least by forming a flare constituting a pyrotechnic decoy which can satisfactorily deceive the approaching vehicles which are equipped with advanced infrared research systems, so that 'they' deviate from the exhaust of an aircraft.

 In a first aspect, the invention relates to a flare constituting a pyrotechnic decoy launched from an aircraft and intended to deceive vehicles which are approaching and which are provided with sophisticated research systems so that they move away from the exhaust of the aircraft, the rocket comprising a block of a pyrotechnic composition of infrared and gas emission, characterized in that the block has a configuration which comprises a cavity arranged symmetrically along the front-rear axis of the block, the cavity being connected to a vent device placed on the rear surface of the block, and an envelope which covers the external surface of the block in front of the rear surface of the block, the envelope being robust enough to remain intact during the entire combustion of the block.

 According to the present invention, thanks to the use of a flare constituting a lure which is provided with a cavity having a vent device on its rear surface, the rocket can be propelled in the same direction as the aircraft with reduction of the speed at which the rocket separates from the aircraft exhaust. When the block is ignited, the combustion spreads almost immediately to all the walls of the cavity and to the rear surface of the block which is not covered. As in conventional blocks, this combustion produces very intense infrared radiation. When the surface of the cavity burns, hot gaseous products are produced and escape from the cavity through the vent device. The forced emission of hot gaseous products by the vent device on the rear surface of the block gives the rocket a forward thrust which propels it forward. Consequently, the flare according to the present invention is less likely to be ignored by a research system which is sensitive to the separation speed of the rocket from the exhaust of an aircraft than conventional flares, and therefore has a more high probability of deceiving a device having a search system so that it moves away from the exhaust of the aircraft. In addition, the flare according to the present invention is more likely to be in the field of vision of a search system sensitive to a sudden increase in the output intensity when the compensation circuit is deactivated and thus, it has a greater high probability of deceiving a device fitted with such a search system by removing it from the aircraft exhaust.

 Clearly, the flare forming a decoy according to the present invention can also deceive research systems which are sensitive both to the speed of separation of the rocket from the aircraft exhaust and to a sudden increase in infrared intensity .

 A single flare forming a lure according to the present invention can deceive different types of sophisticated search systems without the aircraft having to deviate from the trajectory of the approaching craft while maneuvering.

 It should be noted that the rocket must be made so that it has an aerodynamic behavior and that it is ballasted so that the block is ignited a predetermined moment after its launching from the aircraft while the surface having the vent device of the block is turned backwards so that the rocket is propelled in the same direction as the aircraft.

 Preferably, almost the entire rear surface of the block is not covered by the envelope so that the block burns over the entire rear surface and thus creates an infrared source having a large surface which is easily detected by a search system .

 The flare may have a plug of an infrared emission pyrotechnic material covering the rear surface of the block and the vent device, the plug being able to be ignited on its rear-facing surface.

When the plug is ignited on its rear surface, it burns by emitting infrared radiation through the rear surface of the block. The combustion of the plug adjacent to the rear surface of the block causes the rear surface of the block and the walls of the cavity to ignite. Obviously, when the plug has completely burned, it no longer covers the vent device and the block burns and is propelled as described above. The combustion and the thickness of the block can be modified so that the time it takes for the plug to burn completely and ignites the block is modified and thus modifies the time between the launch of the rocket and the ignition of the block. Such a plug is advantageous because it can be used for retarding the ignition of the block until the rear surface of the block is turned in the proper direction so that the rocket is propelled in the same direction as the aircraft.

 Preferably, the ratio of the surface of the cavity to the surface of the vent device is between 10/1 and 60/1. In this range, the forced emission of gaseous combustion products by the vent device is sufficiently limited for the creation of a thrust large enough for the acceleration of a flare of usual size and mass, at a speed which allows reducing the separation of the rocket and the aircraft to a value below the critical value. Furthermore, in this range, it is unlikely that an increase in the pressure in the cavity, due to the fact that the gaseous combustion products cannot escape, will cause the casing to rupture and an explosion of the rocket.

 The pyrotechnic composition has for example a combustion rate which is constant and which is of the order of a few millimeters per second. Consequently, the configuration of the cavity determines how the speed of the rocket varies during the combustion of the block. Preferably, the cavity has a uniform cylindrical shape and the vent device is formed by the cylindrical cavity which penetrates to the rear surface of the block. Advantageously, a cylindrical cavity can have a surface area significantly smaller than the external surface of the block. A uniform cylindrical cavity gives a rocket speed which increases during the combustion of the block. This is due to the fact that, when the surface of the cavity burns, the dimension of the cavity increases and causes an increase in the combustion surface of the walls of the cavity so that the production rate of the gaseous combustion products increases and the quantity of gas which is projected towards the outside of the vent device increases. This effect is compensated to some extent because the area of the vent device also increases when the area of the cavity burns.

 If the cavity extends from the rear surface of the block over the entire axial length of the block, it is preferable that an inert cavity closure member be placed at the front end of the cavity near the envelope. This prevents the combustion of the cavity from progressing along the front surface of the block under the envelope. If the front surface of the block burns, it does not contribute to the regulated propulsion of the rocket nor to the infrared intensity of the rocket and is therefore wasted. In addition, if the front surface of the block burns, it can break the envelope.

 Preferably, the envelope which covers the surface of the block is formed from a metallic material having a melting temperature above 500 C. If the metallic material has a melting temperature below this value, the heat produced during the combustion of the block can cause the envelope to melt and the rocket to explode. Preferably, the metallic material is titanium, a titanium alloy, aluminum or an aluminum alloy. These metallic materials have a high tensile strength so that only a thin layer of the material can be used for the envelope which must remain intact during the entire combustion of the block. In addition, these metallic materials are light and therefore do not increase the mass of the rocket too much.

 Preferably, the envelope is glued to the surface of the block so that it cannot separate from the envelope by sliding. In addition, if the envelope is adjusted and fixed intimately to the surface of the block, it prevents spreading of the combustion of the block from the rear surface of the block along the surfaces covered by the envelope. The combustion of the surfaces of the block which are covered may not contribute to obtaining a regulated thrust or to the emission of infrared light by the rocket and therefore causes a waste of the pyrotechnic composition. In addition, the combustion of the coated surface can cause the envelope to rupture and therefore an explosion of the rocket.

 Preferably, the rocket has an aerodynamic collar which is placed symmetrically around the front-rear axis of the rocket, this collar being slidably mounted on the rocket and being able to come out at the rear of the rocket, the collar having a annular rim formed at its front end and which can cooperate with an annular rim of the rear end of the envelope. When the block is ignited, the aerodynamic collar is turned towards the rear of the rocket by the pressure of the gases, it slides relative to the envelope until the annular rim of the front end of the collar is in contact of the annular rim of the rear end of the envelope.

In the extended position, the collar stabilizes the flight of the rocket.

 The preferred pyrotechnic material for infrared and gas emission is an oxidizing halogenated polymer and an oxidizable metallic material which can react exothermically to each other upon ignition for the emission of infrared radiation, and an organic binder ensures the bonding of the halogenated oxidizing polymer and oxidizable metallic material. The preferred pyrotechnic material may also prefer an oxidizing salt, such as sodium nitrate or perchlorate, intended to modify the spectrum of the infrared radiation produced during the combustion of the material.

 Such pyrotechnic materials which give off gases are well known in the art. When such a pyrotechnic gas-generating material is ignited on its surface, the surface layer of the halogenated polymer oxidizes the metallic material which emits infrared radiation and the corresponding metallic halide formed is released in gaseous form due to the high temperature of the reaction. oxidation (2000 "C). In this way, the combustion burns from its surface inward until the entire composition has burned. Suitable halogenated oxidizing polymers are well known and include in particular polytrifluorochlorethylene and copolymers trifluorochlorethylene and for example vinylidene fluoride. Organic binders which are likewise suitable are well known and contain chlorinated paraffins with unbranched chain, such as "Alloprene" and "Ceroclor", and polyvinyl chloride can also be used. Suitable oxidizable metallic materials are magnesium, an alloy magnesium and aluminum, aluminum, titanium, boron and zirconium.

 The halogenated oxidizing polymer used in the preferred pyrotechnic composition is preferably a fluorinated polymer because fluorine is a better oxidizing agent than all other halogens and thus, fluorinated polymers react more vigorously with the metallic material.

Obviously, the higher the reaction speed, the higher the gas evolution speed and the higher the intensity of the infrared radiation emitted. Preferably, there is a high percentage of fluorine in the fluoropolymer. Examples of fluoropolymers are copolymers of tetrafluoroethylene with perfluoropropylene, homopolymers of perfluoropropylene and copolymers of perfluoropropylene with vinylidene fluoride, homopolymers of hexafluoropropylene and copolymers of hexafluoropropylene with vinylidene fluoride.

 Preferably, the oxidizing fluoropolymer is polytetrafluoroethylene. Polytetrafluoroethylene is a compound which is well known in the field of pyrotechnics. Polytetrafluoroethylene has a high percentage of fluorine and is known to react vigorously with oxidizable metallic materials from the group listed above. Preferably, a mixture of granular grade polytetrafluoroethylene and grade lubricant polytetrafluoroethylene are used in the preferred pyrotechnic composition. The variation in the quantities of the different qualities of polytetrafluoroethylene in the pyrotechnic composition makes it possible to maximize the combustion speed of the preferred pyrotechnic composition for a whole range of altitudes (that is to say oxygen concentrations).

 Preferably, the preferred pyrotechnic composition contains 15 to 50% by weight of polytetrafluoroethylene and 35 to 70% by weight of magnesium. The ratio of polytetrafluoroethylene to magnesium is not stoichiometric and there is an excess of magnesium. In general, there must be an excess of the oxidizable metallic material relative to the oxidizing halogenated polymer because, at the lowest altitudes, the oxygen present in the air reacts with the metallic material. In addition, if the organic binder is fluorinated, it also reacts with the metallic material. The ratio of the oxidizing halogenated polymer to the oxidizable metallic material must be chosen so that the smallest possible amount of one or the other material remains without reacting when the block burns with various concentrations of oxygen.

 Preferably, the organic binder is a fluorinated organic binder, for example a tripolymer of vinylidene fluoride, hexafluoropropylene and tetrafluoroethylene.

The advantage of using a fluorinated organic binder is that the binder associates during the reaction because it also forms an oxidizing agent. Preferably, the fluorinated organic binder is a copolymer of vinylidene fluoride and hexafluoropropylene, for example from "Viton" A. The "Viton"
A coats the oxidizing halogenated polymer and the oxidizable metallic material and binds them very well.

 The preferred pyrotechnic composition preferably contains 1 to 15% by weight of the organic binder. In general, the greater the amount of organic binder used, the safer the treatment of the preferred composition. Generally, the higher the amount of binder used, the easier it is for the preferred composition to ignite, but the rate of combustion decreases.

In a second aspect, the invention relates to a flare constituting a pyrotechnic decoy, comprising
a first block formed of a set of separate pieces, practically without cavity and grouped together in a very dense manner, of a pyrotechnic composition of infrared emission emitting gases and which is contained in an airtight container intended to rupture and to distribute the separate pieces when they are subjected to a predetermined internal pressure due to the combustion of the pyrotechnic composition which gives off gases,
a second block according to the first aspect of the invention, the second block being placed in front of the first block, and
a device for launching and priming the second block for a predetermined time after the priming of the first block.

 This second aspect of the present invention is more effective than the first aspect against research systems which are sensitive to an initial increase in infrared intensity during the ignition of a decoy.

This is due to the fact that the initial rise in infrared intensity per unit mass of the first block is much greater than that produced by a block according to the first aspect of the present invention and therefore has a greater probability of activate the compensation circuit of such a search system.

 When the first block is ignited, the combustion spreads quickly on the surface of the block and further penetrates quickly into the block along the interfaces of the pieces. The gaseous combustion products of the pieces increase the pressure in the container and increase the rate of combustion of the pieces to several meters per second so that practically all the pieces are ignited in a fraction of a second, i.e. all the pieces are practically ignited well before the end of the combustion of the first flaming pieces. When the pressure in the container, due to the accumulation of gaseous products, reaches the predetermined internal pressure, the container ruptures. When the container ruptures, the first block bursts into its constituent pieces due to the release of gaseous products at the interfaces of the pieces. The different pieces have a combined surface which is greater than the surface of the first block so that the pyrotechnic composition which constitutes the first block burns faster than if it were a single homogeneous block. In addition, given the increase in surface area, the pieces decelerate much more quickly under the action of air resistance. This quickly reduces the speed of the air stream over the pieces and thus quickly reduces the cooling effect of the air stream so that the particles burn very quickly. As the particles burn quickly, they give off a high intensity of infrared radiation for a short time.

 As indicated previously, the increase in infrared intensity can cause the activation of a compensation circuit by the search system. The launching and priming device is arranged so that, when the compensation circuit is deactivated, the second block burns in the field of vision of the search system and emits infrared radiation, and the machine is deceived by attraction towards the second block and not towards the exhaust of the aircraft.

 A search system sensitive to the separation speed of the rocket and the aircraft can ignore the first block but does not ignore the second powered block. The rocket constituting a decoy in the second aspect of the present invention is also more effective than that of the first aspect against research systems which combine the two aforementioned research systems. The flare of the second aspect of the present invention does not require an operation of the aircraft.

 Preferably, the sealed container contains both the first and the second block. Preferably, part of the sealed container is formed from the envelope of the second block.

 Preferably, the separate pieces which constitute the first block are formed of a pyrotechnic composition releasing gases, having a combustion speed of between 5 and 15 cm / s in air at atmospheric pressure.

A pyrotechnic composition having such a high rate of combustion is preferable because it allows almost all of the separate pieces to be ignited in a fraction of a second so that the first flaming pieces are not about to stop burning by the time where the last pieces ignite.

 Preferably, the predetermined internal pressure of rupture of the container is the pressure due to the combustion of the pyrotechnic composition at the earliest time at which all the practically separated pieces are ignited. It is advantageous that almost all of the pieces are ignited before the container ruptures because the non-ignited pieces cannot be ignited when the first block bursts and they are therefore wasted.

In addition, it is advantageous for the container to rupture soon after all of the pieces have been ignited so that the pieces will burn as long as possible after the block has burst.

 Preferably, the first block comprises pieces formed of a pyrotechnic composition which has a sticky consistency so that the pieces are coherent for the formation of the first block under pressure. Pyrotechnic compositions having such a consistency are well known and are very convenient since there is no need to glue the pieces together.

 In a variant, the separate pieces which constitute the first block can be bonded by a coherent pyrotechnic priming composition which gives off gases for the formation of the block. This embodiment is particularly advantageous when the separate pieces are difficult to ignite at high temperature (that is to say in the presence of low concentrations of oxygen).

After ignition, combustion quickly spreads by the priming composition between the pieces and ignites them. The combustion of the priming composition and the separate pieces cause the release of gaseous combustion products. The release of gases between the pieces causes the block to burst into its constituent pieces.

 Preferably, the separate pieces which form the first block each have a volume of at least 5 mm. If the separate blocks are smaller, the time it takes for the cloud of burning pieces to burn may not be long enough for the search system to detect the rocket.

 Preferably, the combined surface of the separate pieces which constitutes the first block is between 5 and 75 times the surface of the block. In this range, the deceleration of the cloud of pieces is significantly greater than the deceleration of the block so that the current of cooling air circulating on the pieces that burn is significantly reduced.

 The pyrotechnic composition of the first block preferably contains 15 to 45% by weight of activated fibrous carbon impregnated with a metal salt and 55 to 85% by weight of the preferred pyrotechnic composition of the first aspect of the present invention, and 1 to 6% of organic binder used in the preferred pyrotechnic composition. The addition of impregnated activated fibrous carbon increases the rate of combustion of the first block and thus increases the initial increase in infrared radiation produced when the first block is ignited.

 The activity of the fibrous carbon, measured by the specific heat of wetting by a silicone, is preferably between 20 J / g (low activity) and 120 J / g (high activity). Preferably, the concentration of the metal salt in the activated fibrous carbon impregnated is such that the carbon contains 1 to 20% by weight of the metal. The presence of a metal salt in this range facilitates ignition and maintains the combustion of the carbon in the pyrotechnic composition. Preferably, the metal salt is a copper salt such as sulphate, nitrate, acetate and copper chloride, since these salts are easily deposited on the fibrous carbon and give high rates of combustion in the fibrous carbon in oxygen-poor atmospheres. Other metal salts can also be used, for example aluminum and zinc salts.

 Preferably, the activated fibrous carbon is in the form of an activated carbon fabric, the fabric being preferable since it can be coated with a mixture of the other constituents of the pyrotechnic composition by giving a uniform interface between the carbon and the others. constituents of the composition. The separated fibers can be spaced less uniformly in the composition so that parts of the low-carbon composition can burn with relatively low infrared intensity. An activated carbon felt can be coated with a mixture of the other constituents so that it gives a result similar to that of the fabric, in place of such a fabric.

Other characteristics and advantages of the invention will emerge more clearly from the description which follows, given with reference to the appended drawings in which
Figure 1 is a longitudinal section of a flare constituting a lure in a first aspect of the invention;
FIG. 2 is a graph representing the apparent intensity of the radiation as a function of time when the rocket represented in FIG. 1 is launched and ignited at an altitude of 300 m and a speed of 200 m / s
Figure 3 is a graph showing the speed of the flare as a function of time when the rocket shown in Figure 1 is launched and ignited at an altitude of 300 m and a speed of 200 m / s
Figure 4 is a longitudinal section of a flare constituting
Figure 7 is a longitudinal section of a second embodiment of a flare constituting a decoy in the second aspect of the invention;
Figure 8 is a graph showing the apparent radiation intensity as a function of time when the rocket of Figure 7 is launched and ignited at an altitude of 300 m and a speed of 200 m / s
FIG. 9 is a graph representing the speed of the flares constituting a lure as a function of time for four rockets similar to those represented in FIG. 6 which are launched and ignited at an altitude of 300 m and at a speed of 200 m / s; and
Figure 10 is a graph showing the variation
3 of the weight of metal salt per fraction of 50 cm of water and for 5 g of a charcoal fabric as a function of the percentage of metal of the treated fabric used in the preferred composition for the first block of the second aspect of the present invention.

 The preferred pyrotechnic composition A which constitutes the block 2 and the plug 6 of FIG. 1, the block 54 of FIG. 4 and the block 104 and the plug 106 of FIG. 7, is prepared in the following manner. 25 g of "Viton" A are dissolved in 250 cm3 of acetone, and the solution is stirred vigorously. A larger amount of acetone can be added during the treatment for the formation of a mixture having a consistency such that it can be easily stirred and for the replacement of the acetone which evaporates. 275 g of magnesium, 160 g of polytetrafluoroethylene of granular quality and 40 g of polytetrafluoroethylene of quality for lubricant are added to the solution with vigorous stirring of the mixture continuously. Then 1.2 l of hexane are added and the composition of magnesium, polytetrafluoroethylene and "Viton" (preferred pyrotechnic composition A) is separated from the mixture by precipitation. Composition A is separated from the solution in hexane and acetone by vacuum filtration. Composition A is washed three times using 1.2 l of hexane, filtered under vacuum each time.

Composition A can then dry naturally. When dry, composition A is compressed to a pressure of about 64.106 Pa for the formation of a solid block.

 The pyrotechnic composition B which constitutes the plug 18 of FIG. 1 is formed by the preceding process, but contains 120 g of polytetrafluoroethylene of granular quality and 80 g of quality polytetrafluoroethylene for lubricant, instead of 160 g and 40 g respectively.

 Pyrotechnic composition B has a lower combustion rate than pyrotechnic composition A.

We now refer to Figure 1; a block 2 and a first plug 6 formed from the pyrotechnic composition
A consist of a single cylindrical block of composition
A which has a diameter of 50 mm and a length of 130 mm. The composition block A has a cylindrical cavity 4 placed symmetrically with respect to the front-rear axis 8. The cavity 4 is arranged over 115 mm from the front surface 10 of block 2 to the rear surface 12 of block 2. An organ inert 14 for closing the cavity formed of an insulating material which can withstand high temperatures in the cavity 4 when composition A burns, for example "Tufnol", is mounted intimately at the front end of the cavity 4. The second cylindrical plug 18 which has a diameter of 50 mm and a length of 5 mm and which is formed of a pyrotechnic composition B which burns more slowly is compressed on the rear surface of the first cylindrical plug 6. Block 2, plug 6 and the plug 18 have a configuration such that they are intimately fitted in an envelope 16.

The block 2 and the plugs 6 and 18 are fixed inside the envelope 16 by an adhesive which withstands high temperatures, for example "Araldite". The casing 16 is formed from an aluminum alloy and has a thickness of about 0.5 mm, but other metals or alloys with high melting temperature, which are light and have a high tensile strength , can also be used, for example titanium and its alloys. The envelope 16 is open at its rear end and is disposed a short distance behind the second plug 18. A rear plate 20 is mounted so that it can slide at the rear end of the envelope 16 until that it is in contact with the rear surface of the second plug 18. The rear plate 20 is fixed in place by crimping the lower end of the envelope 16 around it. The back plate is formed from a metal of low density, for example aluminum, and has holes drilled for the positioning of a first load 28 with delay, of a shutter 30 with spring, of a second load 32 overdue and 24 charge of eviction. The first and second delay charges 28 and 30 are formed of a gasless delay initiator material, for example a mixture of boron and bismuth oxide. The shutter 30 which separates the charges 28 and 32 is held in place by the internal surface of a launching tube (not shown) from which the flare forming the lure, designated by the general reference 1, is launched.

The expelling charge 14 is a propellant charge, for example a gunpowder charge.

 The flare constituting the lure operates as follows. When an aircraft detects the arrival of a machine, the aircraft computer transmits a signal for triggering the expulsion charge 24 and the first delay charge 28. When the charge 24 is ignited, it burns by creating a large volume of gaseous products which accumulate behind the rocket in the launch tube (not shown). When the pressure of the gaseous products reaches a predetermined value, a cap (not shown) which covers the front end of the launch tube and which retains the rocket in the launch tube breaks and the rocket is driven out of the tube launch.

When the rocket leaves the launch tube, the shutter 30 moves elastically towards the outside of the rear cap 20 and the charge 28 initiates the delay charge 32. The charge 32 then ignites the second plug 18. When the plug 18 burns , the combustion quickly spreads to the rear surface and the rear plate 20 is expelled at the rear of the casing 16 by the gaseous combustion products thus produced. The second plug 18 burns and its rear surface emits infrared radiation. The combustion cannot extend to the other surfaces of the plug 18 because of the adjustment of the envelope 16 and of the plug 18. The rear surface of the first plug 6 is ignited by combustion of the second plug 18. The first plug 6 burns on its rear surface and emits infrared radiation until it has reached the rear surface of block 2 and ignites it. When block 2 burns, combustion quickly spreads to the rear surface of block 2 and to the walls of cavity 4. Combustion cannot spread to the other surfaces of block 2 because of the presence of the envelope 16 and the inert plug 14. The gases produced when the walls of the cavity 4 burn S 'escape from the cavity 4 through the rear end 22 of the cavity 4 which is no longer closed and thus forms the vent device. The powerful displacement of the hot gases in the vent device 22 from the rear surface of the block 2 gives the rocket a forward thrust which propels it forward. The aerodynamic design of the rocket, in particular the position of the center of gravity of the rocket and the delay between the launch of the rocket and the ignition of block 2 in combination with the direction of the rocket launched by the aircraft ensures the setting from the front surface 10 of block 2 towards the aircraft in the direction of movement of the aircraft when block 2 is on.

 We now refer to FIG. 2 which shows how the intensity of the radiation of the rocket varies over time during its combustion. The initial increase in intensity, between 2 and 2.5 s up to 2 kW / sr corresponds to the combustion of the plug 18 which has a relatively slow combustion and therefore produces a relatively low intensity. The subsequent increase in intensity, between 2.5 and 3.5 s, corresponds to the combustion of plug 6 which burns faster and therefore gives greater intensity.

The rapid increase in intensity between 3.5 and 5.5 s can reach 11 kW / sr and corresponds to the combustion of block 2.

This increase in intensity is due to the constant increase in surface area of the combustion walls of the cavity when the block burns. Obviously, the larger the composition that burns, the higher the amount of infrared radiation emitted from the rear of the rocket.

 We now refer to Figure 3 which shows how the speed of the rocket 1 varies over time during combustion. The initial reduction of the rocket speed from 180 to 50 m / s, between 0 and 3.5 s is due to the deceleration due to the resistance of the air. When block 2 is ignited between 3 and 3.5 s, the speed of the rocket begins to increase. This is due to the fact that the rocket is propelled by the projection of the combustion gases at the rear of the block as described above. FIG. 3 indicates that, in the first second of combustion of block 2, its speed goes from 50 to 120 m / s approximately.

 We now refer to Figure 4; the rocket shown, bearing the general reference 50, comprises a first block 52 and a second block 54.

 The first block 52 is formed of a pyrotechnic composition C which is produced in the following manner.

20 g of "Viton" A are dissolved in 200 cm3 of acetone and 179 g of granular magnesium, 16 g of "Viton" A, 104 g of polytetrafluoroethylene of granular quality and 26 g of quality polytetrafluoroethylene for lubricant are added to the resulting solution. The resulting mixture is stirred so that it forms a suspension which has a consistency allowing its spreading. The suspension is then coated uniformly on 150 g of a commercially available "C-Tex" carbon fabric treated with copper, which can be obtained from Siebe Gorman and Company
Limited. This is achieved by spreading the suspension over the fabric with a spatula. The copper-treated "C-Tex" fabric was impregnated with about 11% by weight of copper. The coated fabric can dry for a few hours until the acetone in the fabric has evaporated, with a rubbery coating on the fabric.

Alternatively, the activated and impregnated carbon fabric may be formed by impregnating a charcoal fabric, for example an untreated "C-Tex" carbon fabric, also available from Siebe Gorman and
Company Limited, with water soluble metal salts as follows. About 5 g of cloth (25 x 15 cm)
3 dried at 105 "C are immersed in 50 cm of an aqueous solution of the metal salt for 2 min at 90" C. The fabric is then removed, drained and dried. Quantities
3 approximate copper salts per 50 cm of water and 5 g of dry fabric, necessary to obtain the necessary percentages of copper in the fabric, are shown in Figure 10. The operation can be carried out at another scale depending on the amount of impregnated activated carbon fabric that is required.

 The second block 54 is formed of a pyrotechnic composition A. The second block 54 has a cylindrical shape 45 mm in diameter and 120 mm in length. A cylindrical cavity 56 8 mm in diameter is drilled symmetrically around a front-rear axis 60 of the rocket 50, the cavity being arranged on the rear surface 58 of the block 54 to a depth of 80 mm. The second block 54 fits intimately into an internal envelope 62 and is bonded thereto which is formed from an aluminum alloy having a thickness of approximately 0.5 mm. The rear end of the casing 62 has an outer annular lip 63. A cylindrical collar 64, having an internal diameter of 31 mm, is fitted on the lip 63 and the casing 62 so that it can slide. The collar has an annular lip 66 placed at its front end and which is intended to cooperate with the lip 63 of the casing 62. The collar 64 has a length of 128 mm and, in its non-extended position, it is disposed at the rear of envelope 62 for a short distance.

 A strip of fabric coated with composition C, having a width of 20 mm, is wound intimately to form the first cylindrical block 52 which has a diameter of 48 mm. The fabric winding is retained so that it does not unwind by stapling the free end of the roll onto the body. The block 52 is placed behind the block 54 and just touches the block 54. The block 52 has a strip of an initiating member 83 placed on its surface and which goes from the second delay charge 84 to the block 54. The composition priming is the same as that which is spread over the activated carbon fabric, during the manufacture of composition C.

 The blocks 52 and 54, the casing 62 and the product 64 having the aforementioned configurations are placed so that they can slide in an external cylindrical casing 67 closed at its front end and which is formed from an aluminum alloy having a thickness of 0.5 mm and an external diameter of 55 mm. A rear plate 68 identical to the rear plate 20 is fixed to the open rear end of the outer casing 67 as described above for the rear plate 20.

 The flare constituting a decoy 50 represented in FIG. 4 operates in the following manner.

When an aircraft detects the arrival of a device, its computer transmits a signal to initiate the expulsion charge 64 and the first delay charge 78, and the rocket is launched at the rear of the aircraft and is primed as described for rocket 1. When launched, its rear end is directed in the direction of movement of the aircraft. The second delay charge 84 ignites the priming member 88 which ignites the first block 52 and the second block 54. The combustion gases drive out the rear plate 68 and the block 52 outside the rear of the outer casing 67. The combustion gases also drive the collar 64 backwards until the internal lip 66 of the collar 66 is in contact with the external lip 63 of the casing 62. In its extended position, the collar 64 stabilizes the flight of the rocket 50. The block 52 burns quickly in the air by emitting high intensity infrared radiation. The combustion of the block 54 extends rapidly from its rear surface to the walls of the cavity 56.

When the block 52 leaves the casing 67 and the collar 64 comes out, the center of gravity of the rocket is located towards the front end of the rocket so that the latter rotates in the vertical plane around its center of gravity. In this way, the rocket rotates to be turned in the direction of the aircraft at about the same time as the cavity 56 begins to burn so that the rocket is propelled in this direction. Block 54 burns in the same way as block 2 of rocket 1.

 We now refer to FIG. 5 which shows how the intensity of the radiation of the rocket 50 varies over time when it burns. The initial rapid rise in intensity between 2.5 and 3.5 s which can reach 7 kW / sr corresponds to the combustion of block 42. The second weaker peak between 3.5 and 5 s, which reaches approximately 4 kW / sr, corresponds to the combustion of block 54. The rocket 50 is perfectly suited against a search system sensitive to an initial rise in intensity produced when a rocket is ignited. The combustion of the first block 52 causes a very rapid rise in intensity which is likely to activate the compensation circuit of such a search system. The combustion of the second block 54 occurs during the period in which the compensation circuit of a usual research system is likely to be deactivated so that the machine can be attracted to the second block 54 away from the exhaust of the aircraft.

 Reference is now made to FIG. 6 which shows how the speed of a type 50 rocket varies over time during combustion. The initial speed reduction from 140 to 100 m / s between 0 and 1 s is due to the deceleration due to air resistance. When the block 54 is ignited to approximately one second, the speed of the rocket remains constant at approximately 100 m / s between 1 and 3 s.

This is due to the fact that the rocket is propelled by the projection of the combustion gases at the rear of the block 54.

 It should be noted that the infrared intensity and the speed of the block 54, when it burns are much lower than the infrared intensity and the speed of the analog block 2 shown in FIG. 1 when it burns under similar circumstances. It is believed that this is partly due to the fact that the first block 52 burns very vigorously and can disturb the second block 54 by causing its combustion by the surfaces of the block 54 which are covered by the envelope 62.

 We now refer to Figure 7; the flare represented and designated by the general reference 100 comprises a first block 102 and a plug 106 as well as a second block 104.

 The first block 102 is formed from composition C in the following manner. A piece of coated carbon fabric is cut into squares each having 5 mm sides, and 140 g of fabric pieces are compressed at a pressure of 64.106 Pa in the form of the cylindrical block 102 having a diameter of 48 mm and a length of 48 mm.

 The second block 104 and the plug 106 are formed from the same block of pyrotechnic composition A. Block 104 has a length of 115 mm and a diameter of 50 mm and a cylindrical cavity 110 is drilled symmetrically along the front-rear axis. 108. The cavity has a diameter of 8 mm and is arranged over the entire axial length of the block 104. The plug 106 has a length of 5 mm. A member 112 for closing the cavity, formed of "Tufnol", is adjusted at the front end of the cavity 110. The block 104 and the plug 106 are glued in the cylindrical casing 114, closed at its front end, formed 0.5mm thick aluminum alloy. The rear part of the envelope 114 projects behind the plug 106. The block 102 is placed behind the plug 106 and almost touches the plug 106. A rear plate 120 identical to the rear plate 20 is placed behind the block 102 and is fixed thereto by crimping the rear end of the casing 114 around the plate. Block 102 has a strip of priming member 118 placed on its surface from the second charge 132 and the rear plug 106. The priming composition is the same as that which is spread over the activated carbon fabric during manufacture of composition C.

 The flare forming the lure 100 shown in Figure 7 operates in the following manner.

When an aircraft detects the arrival of a machine, its computer transmits a signal to initiate the expulsion charge 124 and the first delay charge 128, and the rocket is launched at the rear of the aircraft as described for the rocket 1 shown in FIG. 1. When it is launched, its rear end is turned in the direction of movement of the aircraft. The charge 132 ignites the priming member 118 which ignites the first block 102 and the plug 106. The release of gases produced by the combustion of the priming member drives the back plate 120 and the first block 102 out of the envelope 114. The rocket 100 is made so that its center of gravity is close to the front end of the rocket so that the rocket 100 rotates around its center of gravity in the same way as the rocket 50 represented on FIG. 4. The combustion of the first block 102 extends on its surface and at the interfaces of the pieces of coated fabric. The release of gaseous combustion products at these interfaces causes the block 102 to burst into its constituent pieces. The coated pieces of fabric quickly detected because they had a large area. The pieces of fabric burn with a high infrared intensity because the speed of air circulation on their surface is reduced.

 Furthermore, the plug 106 burns and ignites the second block 104. The rocket 100 is made so that, when the block 102 ignites the front end of the rocket, it has turned and is in the direction of movement of the plane so that the rocket is propelled in this direction. The second block 104 burns producing hot gaseous products which escape through the vent device 130 as described for block 2 of the rocket 1.

 We now refer to FIG. 8 which shows how the intensity of the radiation of the rocket 100 varies over time during its combustion. The initial increase in intensity between 1 and 2 s reaches 3 kW / sr and corresponds to the combustion of the first block 102. The third peak between 2.5 and 4 s, which reaches 6 kW / sr, corresponds to the combustion of the second block 104. The intensity of the first block 102 was less than that predicted from the results of separate blocks analogous to the first block 102, ignited under analogous conditions.

 Reference is made to FIG. 9 which shows how the speed of four rockets similar to rocket 100 varies over time during combustion. In all four cases, the rockets underwent high acceleration. A flare with a speed profile shown in Figure 9 can satisfactorily deceive a search system sensitive to the speed of separation of the rocket and the aircraft.

Claims (21)

 1. Flare (1) forming a pyrotechnic decoy launched from an aircraft and intended to deceive incoming devices which are equipped with sophisticated research systems, so that these systems are removed from the exhaust of the aircraft, of the type which comprises a block (2) of a pyrotechnic composition which emits infrared radiation and gases, characterized in that the block (2) has a configuration comprising a cavity (4) which is placed symmetrically with respect to the front-rear axis of the block, the cavity having a vent device on the rear surface (12) of the block (2), and an envelope (16) which covers the external surface of the block (2) in front of the rear surface (12 ) of the block (2), the casing (16) being robust enough to remain intact during the entire combustion of the block (2).  2. Rocket (1) according to claim 1, characterized in that a plug (6) of a pyrotechnic material emitting infrared radiation covers the rear surface (12) of the block (2) and the event device (22).  3. Rocket (1) according to any one of the preceding claims, characterized in that the ratio of the surface of the cavity (4) to the surface of the vent device (22) is between 10/1 and 60/1.  4. Rocket (1) according to claim 3, characterized in that the cavity (4) is in the form of a uniform cylinder and the vent device (22) is formed by the cylindrical cavity (4) which extends towards the surface rear (12) of the block (2).  5. Rocket (1) according to claim 4, characterized in that the cylindrical cavity (4) starts from the rear surface (22) of the block (2) and is arranged over the entire axial length of the block (2), and a an inert member (14) for closing the cavity is placed at the front end of the cavity (4) near the envelope (16).  6. Rocket (1) according to any one of the preceding claims, characterized in that the envelope (16) is formed of a metallic material having a melting temperature above 500 "C.  7. Rocket according to claim 6, characterized in that the metallic material is titanium, a titanium alloy, aluminum or an aluminum alloy.  8. Rocket (1) according to any one of the preceding claims, characterized in that the envelope (16) is glued to the surface of the block (2).  9. Rocket (50) according to any one of the preceding claims, characterized in that it has an aerodynamic collar (64) placed symmetrically with respect to the front-rear axis (60) of the rocket, the collar (64 ) being mounted so that it can slide on the rocket and being able to be removed outside the rear of the rocket, the collar having an annular flange (66) placed at its front end and which can be in contact with an annular rim (63) forms at the rear end of the envelope (62).  10. Rocket according to any one of the preceding claims, characterized in that the pyrotechnic composition of infrared and gas emission comprises an oxidizing halogenated polymer and an oxidizable metallic material which can react exothermically with each other during l 'ignition with emission of infrared radiation, and an organic binder.  11. Flare (50) forming a pyrotechnic decoy, characterized in that it comprises  a first block (52) which comprises a set of separate pieces, the set being practically devoid of cavities, the separate pieces being densely grouped and being formed of a pyrotechnic composition capable of emitting infrared radiation and gases, the first block being housed in a sealed container (67, 68) intended to rupture and to distribute the separated pieces when it is subjected to a predetermined internal pressure due to the combustion of the pyrotechnic composition which gives off gases,  a second block (54) analogous to the block of a rocket according to any one of claims 1 to 10, the second block (54) being placed in front of the first block (52), and  a device (74, 78, 84, 88) for launching and priming intended to initiate the first block (52) a predetermined time before the priming of the second block (54).  12. Rocket according to claim 11, characterized in that the sealed container (67, 68) contains both the first and the second block (52, 54).  13. Rocket (50) according to one of claims 11 and 12, characterized in that the separate pieces which constitute the first block (52) are formed of a pyrotechnic composition releasing gases, having a combustion speed of between 5 and 15 cm / s in air at atmospheric pressure.  14. Rocket (50) according to any one of claims 1 to 13, characterized in that the predetermined internal pressure at which the container (67, 68) ruptures, is the pressure created by the combustion of the pyrotechnic composition which gives off gases as soon as substantially all of the separate pieces of the first block (52) are ignited.  15. Rocket (50) according to any one of claims 11 to 14, characterized in that the pieces of the first block (52) are formed of a pyrotechnic composition which has a sticky consistency so that the particles form a first block (52) in a coherent form under pressure.  16. Rocket (50) according to any one of claims 11 to 15, characterized in that the separate pieces which form the first block (52) each have a volume of at least 5 mm3.  17. Rocket (50) according to any one of claims 11 to 16, characterized in that the combined surface of the separate pieces which constitute the first block (52) is between 5 and 75 times the surface of the block.  18. Rocket (50) according to any one of claims 11 to 17, characterized in that the pyrotechnic composition of the first block (52) contains 15 to 45% by weight of activated fibrous carbon impregnated with a metal salt, 55 to 85% by weight of the pyrotechnic composition according to claim 13, and 1 to 6% by weight of the organic binder.  19. Rocket according to claim 18, characterized in that the concentration of the metal salt of the activated fibrous carbon impregnated is such that the carbon contains 1 to 20% by weight of metal.  20. Rocket according to one of claims 18 and 19, characterized in that the metal is copper.  21. Rocket according to any one of claims 18 to 20, characterized in that the activated fibrous carbon is in the form of an active carbon fabric.