NL1007966C2 - Expendable infra-red radiator comprises decoy plates having composition of metal and oxidant capable of exothermic combustion reaction upon ignition - Google Patents

Abstract

An expendable infra-red (IR) radiator comprises decoy plates (11) housed within a rupturable container (1). The decoy plates comprise a composition of metal and an oxidant capable of an exothermic combustion reaction upon ignition. An expendable IR radiator comprises a rupturable container; decoy plates housed within the rupturable container and an ignition mechanism for igniting the decoy plates. The decoy plates comprise a composition of a metal and an oxidant capable of an exothermic combustion reaction upon ignition. The composition being such that the combustion reaction produces negligible radiation in the visible or UV regions, following completion of the combustion reaction. The decoy plate comprises hot metal emitting IR radiation.

Description

Expandable infrared abrasives

The present invention relates to expandable infra-red displacement blasting means and in particular to a displacement counter-measure unit or bait flash unit, which is capable of generating an IR disturbance cloud to generate an incoming, with a IR search system equipped rocket to lead away from its intended purpose or to create a hiding IR screen.

Known IR baits flashing units usually comprise pyrotechnic compositions which are bound together with an organic binder and compressed in the form of tablets. When an incoming rocket is detected, a tablet is ignited and launched from the target. The tablet burns over its surface and produces an intense infrared source that can lure the rocket's infrared search system away from the target.

However, advancements in rocket search systems and the development of "intelligent" rocket systems have led to search systems designed to recognize and ignore characteristic characteristics of a bait flash unit. Some intelligent search systems are programmed with a characteristic infrared signature of the intended target, for example the jet of a jet, and will ignore the almost point-shaped radiation source of a conventional flash unit.

Therefore, the need has arisen for a counter-measure unit which radiates over a wide area and which either looks more like the intended target or functions as a screen for the missile system, in particular for larger or slower moving targets.

A known bait flash unit capable of generating a large cloud radiating into the infrared region is described in U.S. Pat. No. 4,624,186. This flash unit comprises a flammable housing comprising a flakes and an ignition acceleration material. These combustible flakes comprise a thin base material, such as paper or metal foil, on which highly flammable paste comprising phosphorus is printed. During use, the flash unit is launched into the air and the ignition acceleration material creates a fireball that passes through the flammable flakes, thereby igniting the highly flammable paste which thereby burns so that it emits IR radiation and through which the flakes are diffused slowly whirl down .1007966 2, creating a disturbance cloud.

A problem of this type of flash unit is that os has a characteristic IR emission spectrum for which some "intelligent" search systems can be programmed to ignore them.

Moreover, these types of flash units are quite expensive. Furthermore, this type of flash unit also radiates in the visible and ultraviolet (UV) areas and produces a large, visible cloud of smoke. This has the disadvantage that it is revealed that a countermeasure has been applied which can indicate that a certain threat has been detected.

Moreover, some "intelligent" search systems use other radiation, such as UV emission, when they decide to ignore some IR sources and therefore they are not distracted by flash units that emit significant amounts of radiation in the visible or UV regions. Moreover, some rocket systems, for example those often used in anti-aircraft ground batteries, require human operators to make a first target acquisition for a particular rocket before the IR search system of that rocket guides it to the required target. This target acquisition is performed visually and therefore, especially at night, illumination of the target by the visible emission from the ignition unit is undesirable.

A well-known type of concealment unit uses activated metal discs (AMDs). These are metal discs made pyrophoric by a process described in U.S. Patent No. 4,895,609. The disks are kept in a storage which, after ejection from the target, tears, so that the disks are released. Because the discs are pyrophoric, they ignite in contact with the air and burn, so that they serve as bait.

However, this type of flame unit is expensive to produce and, due to the pyrophoric nature of the discs, has a relatively large delay before it becomes effective, because the discs must be ejected and released before ignition can occur. For some applications, for example for fast-moving vehicle traps, the limited field of view of some modern search systems means that the disks may be out of the effective view of the missiles at the time the ignition is fully on its way and they will therefore not be effective. are like bait. In addition, the mass of a flash unit of this type can be considerably larger than that of standard iR flash units.

1007966 3

It is therefore an object of the present invention to provide an iR radiation source that solves at least some of the above problems.

According to the present invention, expandable infra-red radiation means are provided, comprising a tearable container, a number of bait plates housed within the tearable container and an ignition means for igniting the bait plates, characterized in that the bait plates comprise a composition of a metal and an oxidizing agent capable of an exothermic combustion reaction after ignition, wherein the composition is selected such that the combustion reaction produces negligible radiation in the visible regions or ultraviolet regions and wherein, after completion of the combustion reaction, the bait plate comprises infrared radiation emitting hot metal.

In use, the container is set up in the air and the bait plates are ignited by the igniting means. The container is then torn, for example by pressure built up within the container, to release the bait plates to form a cloud of IR radiation sources.

Use of a composition of a metal and an oxidizing agent capable of an exothermic combustion reaction after ignition of the bait plates provides a relatively inexpensive flame unit capable of generating a cloud of material strongly in the IR region. broadcast area.

Because the combustion reaction primarily produces heat that can be stored in the hot metal that remains after the reaction has finished, the bait plates produce negligible amounts of radiation in the visible or UV regions during and after the combustion. In daylight, when the bait plates are arranged as a screen or as a bait-ignition unit, the small amount of visible radiation will not be visible against background light. Even at night, releasing the discs means that the annealing of the plates in the visible area will be substantially undetectable in the respective areas. Therefore, the counter-measure unit can be arranged in a hidden way. In addition, a rocket search system will not see any radiation in the UV region that would be characteristic of a bait ignition unit.

Metal that is present after the combustion of the bait plate will be hot due to the heat generated during the combustion and will therefore radiate into the iR region, but will have negligible, visible or UV radiation . The bait is therefore effective longer than the duration of combustion of the bait plates and a bait cloud with a relatively long duration can be produced without the need for slow burning compositions.

As a result, the duration of the combustion reaction can actually be reduced and fast-burning compositions can be selected in view of their heat-generating properties. The combustible composition also has a fast ignition time and the bait plates can be ignited for their release, thereby ensuring that the plates become effective within the field of view of the missiles. Minimizing the duration of ignition of the bait plates is also advantageous because the ignition reaction produces not only heat, but also visible and ultraviolet (UV) radiation.

A further advantage is that, after the combustion reaction has ended, the IR emission spectrum of the bait plate will be characteristic of hot metal, which is expected from a target, for example the hot metal parts of a tank engine or an aircraft exhaust, and that it is not will include a single component that the search system will recognize as artificial and characteristic of a bait.

Moreover, the electrical conductivity of the plates and of any metal that exists after the reaction means that the cloud produced is formed of conductive elements that can reflect HF signals and therefore serves as a large RADAR reflective surface. Due to its conductive properties, the cloud can also reflect all HF signals generated by the target, potentially confusing all systems searching for these signals or, alternatively, the cloud could displace all incident RADAR pulses -30 spreading, which may result in deriving a system that uses active RADAR conduction.

In order to ensure that the bait functions effectively after the combustion, the composition of the bait plates is preferably selected such that the mass of hot metal from a bait plate emitting infrared radiation after combustion is at least 10% of the mass of the bait plate is prior to incineration. For a bait based on hot metal remaining after the reaction, the amount of such metal remaining should be at least 10% of the 1007966 mass of the bait plate to ensure that the plates function efficiently.

Preferably, the composition of the bait plates comprises an excess of metal.

Ignition and combustion of a bait plate produces heat due to the combustion reaction between the metal and the oxidizing agent. The excess metal does not undergo a reaction and absorbs a significant amount of the heat generated during the reaction, resulting in hot metal remaining at the end of the reaction.

It will be apparent to one skilled in the art that by varying the ratio of metal to the oxidant present in the composition of the bait plates, the amount of metal remaining after the reaction can be changed, as well as the amount of Generated heat.

The composition of the bait plates is preferably chosen such that a reaction product of the exothermic combustion reaction between the metal and the oxidizing agent is infrared radiation emitting hot metal.

By producing metal in the combustion reaction, the portion of the bait plate that undergoes a reaction can be large, while the benefits of the presence of metal are maintained after the reaction has ended. Thus, the excess metal portion can be reduced, which could result in more generated heat, while the same amount of metal remaining after the reaction remains.

Alternatively, production of a metal in the combustion reaction means that all the metal from the bait plate could participate in the combustion reaction and that there would nevertheless be hot metal at the end of the reaction. This could make it possible to choose the metal of the plate because of its fuel properties, while the produced metal could be selected for its thermal properties, for example thermal conductivity or melting point.

Metal can suitably be produced by ensuring that the metal of the bait plate is a first metal and the oxidizing agent is an oxide of a second metal. After ignition, the first metal and the second metal oxide undergo a combustion reaction, the oxide of the second metal disintegrating and producing a second metal and the first metal reacting with the liberated oxygen to form an oxide of the first metal.

Suitable metal fuels release large amounts of heat in the combustion reaction and include aluminum, iron, calcium, titanium, silicon, boron, although it will be apparent to one skilled in the art that other metals may be used. The oxidizing agent must be clearly such that it will be reduced in the combustion reaction and release sufficient heat and the person skilled in the art will be able to easily determine suitable oxidizing agents for a particular metal fuel. Suitable aluminum oxidants include, for example, iron oxide, calcium oxide, tungsten dioxide or trioxide, manganese dioxide and sodium chlorate.

An advantageous composition of a bait plate has iron as the metal and potassium perchlorate as an oxidizing agent. This composition is cheap and reliable and produces potassium chloride and iron oxides after combustion. Preferably, 82 to 88% by weight of the bait plate is iron and 18 to 12% by weight of the bait plate is potassium perchlorate. This ratio is optimized to provide maximum thermal and electrical conductivity prior to, during and after combustion, due to the excess iron.

An alternative composition in which metal is produced has aluminum as a metal and iron oxide as an oxidizing agent. This composition produces iron and aluminum oxide after burning. An almost stoichiometric composition of aluminum and iron oxide is preferably used to maximize the efficiency.

A further composition that can be used in which metal is produced has titanium as the metal and manganese dioxide as the oxidizing agent. This composition produces manganese and titanium oxide after combustion. However, it will be apparent to one skilled in the art that other compositions may be used.

Preferably the bait plates comprise a pressed composition of a particle metal and particle oxidant.

Pressing the composition to form the bait plates offers an inexpensive and simple method of manufacture with reliable results. The dimensions of the particles have an effect on the heat of the reaction and can be varied for different applications, although it will be clear to the person skilled in the art that particle sizes must be chosen such that they are not too large to cause an unreasonable 1007966 7 cause serious combustion or cause problems with the ignition, but that they must not be too small so that they can lead to problems with safety and uncontrollability because the plates are too sensitive. The press loads will have to be similar in such a way that a good contact between metal and oxidant is ensured.

The composition of the bait plate can advantageously further comprise a binder material to improve the stability of the plates and to adjust the thermal characteristics of the plates.

Advantageously, the thicknesses of the bait plates are adjusted such that at least some of the bait plates break during use upon release from the tearable container. The shock of ejection into the atmosphere from the tearable container causes the thin plates to break during the ejection. This results in a cloud with IR-emitting parts of different sizes. The particles of different sizes would have different air resistances, which would help in spreading the cloud over a large area. Also, the particles with varied dimensions may, due to their conductive properties, have a greater potential for RADAR reflection.

It is most useful if the bait plates have grooves that run over the surface. Grooves help to break the plates, especially after the combustion reaction between the metal and the oxidizing agent, and can be used either additionally or as an alternative to thin plates. Grooves provide more control over the produced dimensions of the particles, which can be adjusted to the wavelength of the likely RADAR signals. The addition of grooves to the bait plates also speeds up the ignition times of the plates by allowing the hot gases to pass along the grooves.

The composition of the bait plate can also be adjusted such that at least a portion of the metal produced by the combustion of a bait plate is melted. By selecting the composition of the bait plates such that the hot metal produced has a melting point that is lower than the temperature reached by the exothermic combustion reaction, at least a portion of that produced metal will be melted.

Molten metal will radiate into the IR region and will rapidly cool sufficiently to solidify forming various shapes, from droplets to deformed plates, depending on the properties of the metal that was originally melted. These produced shapes will be more effective at scattering incident RADAR radiation and will have a wider range of reflection characteristics.

Suitably the bait plates are separated by intermediate combustible coating material. The coating can serve as a spacer to reduce the weight of the bait and can assist in spreading the bait plates by reducing the tendency of the plates to stick together. A flammable coating will also contribute to the effectiveness of the bait and can be chosen so that it produces negligible visible radiation or UV radiation.

Further advantages and embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which: Figure 1 shows a cross-section of a bait ignition unit according to the present invention; Figure 2 shows a bait plate suitably is for use in the ignition unit, as shown in Figure 1, Figure 3 shows a graph of the relative intensity of infrared radiation with respect to the time for ignition of a typical bait plate suitable for use in a flash unit according to the present invention.

Referring now to Figure 1, a tearable container, generally designated 1, has a cylindrical housing 3 with an open end, the open end being sealed by a cover 5. The cover 5 is held in place by the edges 7 of the open end of the housing 3 are slightly curled into a groove 9 in the cover 5. A number of bait plates 11 are stacked in the housing 3.

A type of bait plate suitable for use in this ignition unit is shown in Figure 2. The bait plate is in the form of a disc 11 provided with a central hole 13. The disc 11 has a diameter of approximately 45 mm and a thickness of 0.6 mm, the central hole 13 having a diameter of 6 mm has. Grooves 15 extend radially from the central hole 13 to the edge of the disc, the grooves being approximately 1 mm wide and 0.4 mm deep.

In a particular embodiment, the disc 11 is formed from a particle composition of 86% by weight of iron (Fe) and 14% by weight of potassium perchlorate (KC104) compressed under a load of about 100 1007966 9 MPa. The iron particles have a size of around 5-15 μιη and the potassium perchlorate particles are larger in size than 45 μηι. After ignition, the iron and potassium perchlorate undergo a combustion reaction and oxides of iron and potassium chloride are formed, the basic reaction being as follows: 3Fe + KC104 - »KCl + Fe304 + Heat (1)

It can be seen that since the atomic weight of iron is approximately 56 and that of potassium perchlorate is approximately 90, the stoichiometric mixture then has approximately 65% by weight of iron with 35% by weight of potassium perchlorate. It is therefore clear that approximately 60% by weight of the disc is present as excess iron. However, during use, the production of other iron oxides would occur and the reaction would be completed by oxygen in the atmosphere, whereby the actual amount of excess iron would be lower than this. The typical temperature reached by such a disc would be about 1000 ° with a burning rate of about 10 cm / sec.

In an alternative embodiment, the disc comprises a pressed particle composition of aluminum (Al) and iron oxide (Fe 2 O 3). After ignition of this mixture, the aluminum and iron oxide undergo a combustion reaction and iron and aluminum oxide are produced, the principal reaction being as follows: 2Al + Fe 2 O 3 - »2 Fe + Al 2 O 3 + Heat (2)

Here it can be seen that the reaction produces iron, whereby inflammation of the disc 11 results in the production of red hot iron. The disk 11 has an almost stoichiometric ratio of aluminum to iron oxide, with 30% by weight of the disk being aluminum.

In a third embodiment, the disc 11 could comprise a pressed particle composition of titanium (Ti) and manganese dioxide (MnO 2), which after ignition undergoes a combustion reaction and produces manganese and oxides of titanium, one of the principal reactions being follows:

Ti + MnO 2 * Mn + TiO 2 + Heat (3) 1007966 10

It will of course be clear to a person skilled in the art that other suitable metal fuels and oxidizing agents can be used.

Referring back to Figure 1, the plates 11 are stacked, an ignition cord 17 from a position adjacent to the lid 5 passing through the center of the bait plates 11 to form a coil 19 at the closed end of the housing 3. The ignition cord has its ignition end 21 in addition to an ignition transfer means 23 in the cover 5. A piston 25, for example a board of cardboard, plastic or aluminum, for example with a diameter equal to or slightly smaller than that of the inside of the housing, is present between the ignition cord 21 and the stack of bait plates 11.

For certain applications, the bait plates can be stacked with a flammable coating (not shown) as interlayers in order to reduce the tendency of the ignition plates to stick together and to reduce the amount of plates in the stack and thereby the weight of the bait .

During use, a pyrotechnic mixture is ignited, for example by a standard electrical igniter (not shown), and the tearable container is arranged in the air. As soon as the tearable container is free from its housing, spring 27 is released, thereby allowing the inflammatory stimulus to move downward in the tube 29 to ignite delay 23. Delay 23 allows the flame unit to move out of its housing before the ignition end 21 of the ignition cord 17 ignites. Should the frangible container continue to jam, spring 27 prevents propagation of the inflammatory stimulus, thereby preventing the bait ignition unit from being ignited within its housing.

Ignition of the ignition end 21 of the ignition cord 17 causes the cord to burn rapidly, causing the bait plates 11 to ignite as soon as the fireball propagates along the cord. The gases generated from this combustion and ignition of the bait plates 11 cause a build-up of pressure in the housing, which is sufficient to eject the cover 5. The first pair of bait plates 11 is likely to fall out of the house. Meanwhile, the combustion of the coil 19 of the ignition cord produces a large amount of gas which drives the piston 25 to eject the ignited bait plates 11.

In general, the spread of the bait plates 11 can be changed by selecting an ignition train that generates more or less gas. A useful ignition cord may be, for example, a magnesium / Viton / Teflon (MTV) ignition cord that generates useful amounts of gas to disperse the plates over a large area.

The characteristic variation in intensity of the total IR radiation emission of a bait plate without a grooved surface is shown in Figure 3. The ignited plate was a 0.5 mm thick disc of 86% iron and 14% potassium perchlorate with a diameter of 47 mm.

It can be seen from the graph that even without grooves in the surface, the disc shows a very rapid rise time from ignition to maximum intensity, thereby ensuring that the bait starts its operation within the field of view of the rocket. The peak intensity drops relatively quickly, but the intensity remains high on average for a long duration due to the radiant metal that remains present after the reaction. Thus, the ignition unit provides a fast response time coupled with a long duration and is suitable for use with fast or slow targets. Also, since the first ignition can trigger a counter-control unit and cause the rocket to ignore its guidance system for a short time, when the guidance becomes active again, the bait will still emit radiation and function as bait, but without any of the tell-tale characteristics of well-known baits.

1 ü 0 7 9 6 6

Claims (16)

An expandable infrared blasting means comprising a tearable container (1), a plurality of bait plates (11) housed within the tearable container (1) and an ignition means (17) for igniting the bait plates (11) characterized in that the bait plates (11) comprise a composition of a metal and an oxidizing agent capable of an exothermic combustion reaction after ignition, the composition being such that the combustion reaction is negligible radiation in the visible areas or ultraviolet producing regions and wherein, upon completion of the combustion reaction, the bait plate comprises infrared radiation emitting hot metal. 2. Expandable infrared blasting means according to claim 1, characterized in that the composition of the bait plates (11) is selected such that the mass of hot metal emitting infrared radiation emitting infrared radiation at least 10% after burning of the bait plate of the bait plate mass prior to incineration. Expandable infrared blasting means according to one of the preceding claims, characterized in that the composition of the bait plate (11) comprises a stoichiometric excess of metal. 4. Expandable infrared blasting means according to one of the preceding claims, characterized in that the composition of the bait plates (11) is chosen such that a reaction product of the exothermic combustion reaction between the metal and the oxidizing agent is infrared. radiation emitting hot metal. Expandable infrared blasting means according to claim 4, characterized in that the metal is a first metal and the oxidizing agent is an oxide of a second metal. Expandable infrared blasting means according to one of the preceding claims, characterized in that the metal is selected from the group consisting of aluminum, iron, calcium, titanium, silicon and boron. Expandable infrared blasting means according to one of claims 1 to 3, characterized in that the metal is iron and the oxidizing agent is potassium perchlorate. Expandable infrared blasting means according to claim 7, characterized in that 82 to 88% by weight of the bait plate is iron and 18 to 12% by weight of the bait is potassium perchlorate. 9. Expandable infrared abrasives according to any one of claims 1 to 6, characterized in that the metal is aluminum and the oxidizing agent is selected from the group consisting of iron oxide, calcium oxide, tungsten oxide, tungsten trioxide, manganese dioxide and sodium -chlorate. Expandable infrared blasting means according to claim 9, characterized in that the oxidizing agent is iron oxide. 11. Expandable infrared blasting means according to any one of claims 1 to 6, characterized in that the metal is titanium and the oxidizing agent is manganese dioxide. 12. Expandable infrared blasting means according to one of the preceding claims, characterized in that the bait plate (11) comprises a pressed composition of a particle metal and particle oxidizing agent. Expandable infrared blasting means according to any one of the preceding claims, characterized in that the composition of the bait plates further comprises a binder material. 30 Expandable infrared blasting means according to one of the preceding claims, characterized in that the thicknesses of the bait plates (11) are adjusted such that during use at least some of the bait plates break when spread out of the tearable container. 35 Expandable infrared blasting means according to one of the preceding claims, characterized in that the bait plates (11) have grooves (15) that run over the surface. 1 007966 Expandable infrared blasting means according to any one of the preceding claims, characterized in that the composition of the bait plates is adapted such that at least some of the hot metal remaining after the combustion of a bait plate is melted. 5 Expandable infrared blasting means according to one of the preceding claims, characterized in that the various bait plates (11) have intermediate layers of combustible coating material. 10 ***** 1007966