EP0108939A2 - Fume generating charge and process for generating a fume impervious to visible and infrared radiation - Google Patents

Abstract

The invention relates to a mist ejection body consisting of a socket (5) with an ignition device and a mist (1) and disassembling primer (3, 4). According to the invention, two or more mist sets (1) are arranged one above the other in separate, interconnected containers (7), the ignition set (3, 4) being arranged centrally in the mist sets. The smoke ejection body contains at least one fog set (1) that generates an optical fog and at least one fog set (1) that generates an infrared-absorbing fog. The process for producing a mist that covers both optically and in the infrared region is that an exothermic mist is burned off and a powder, preferably a lamellar metal powder, is suspended in it.

Description

From "Reports of the Institute for Chemistry of Propellants and Explosives of the Fraunhofer Gesellschaft", Jahrestagung 1975, Karlsruhe 1975, page 185-194 it can be seen that infrared radiation of certain wavelengths is selectively absorbed by atmospheric components, which creates so-called "atmospheric windows" . These are at wavelengths from 0.7 to 1.5 µm up to 8 to 12 µm. It therefore made sense to use this knowledge using Rayleigh's law and to use dusts as fog for camouflage purposes, see e.g. DE-AS 27 29 055. However, these dusts only give an unsatisfactory optical coverage and have a relatively high sink rate.

An object of the invention is to provide a device with which it is possible to produce a mist which is both optically opaque and IR-absorbing, the IR-absorbing component having a longer-lasting effect.

This object is achieved by a device with the features of claim 1.

Advantageous designs can be found in the subclaims.

The invention and its advantages are explained in more detail below.

The effect of the device is probably as follows: The missile mist blower fires on its trajectory (or also lying on the ground) the detonating primer for the optically effective fog set. This is broken down into many small particles that fall onto the floor and thereby generate fog and heat. This creates a large number of small upwind fields.

Immediately after the optical mist set has been ignited, the ignition charge for the powder, which distributes the powder in the optical mist, is also ignited. The effect of the large number of thermal fields makes it possible to keep the powder mist in suspension much longer than would be the case without the addition of optical mist. If necessary, suspension and charge separation effects also play a role.

A combination has proven to be particularly effective in which the IR set is a metal powder and the optical mist mixture consists of pressed bodies which are layered on top of one another and provided with slits, the slits forming a channel for receiving the ignition charge. These compacts burn even in disassembled state as relatively large particles, delayed and not spontaneously, so that optical fog is constantly supplied, but also discrete thermal fields are supported, in which the descending powder particles can be held in suspension or even moved upwards.

The present invention provides for a mist set, here the powder, to be accommodated in a separate container in the can, separate from the optical mist set. This container has a central pipe socket for receiving the primer.

This simple solution makes it possible to adapt the primers to the fog components, i.e. assign the optimal sentence to each fog. It is intended to seal the bottom of the nozzle with a film, which facilitates assembly and prevents chemical reactions between them.

Particularly good results are achieved if a lamellar powder, preferably copper powder, is used as the powder. This powder is on the market and has a specific surface area of 3200 to 16,000 cm ² / g and a diameter of 1.9 to 0.45 µm. In combination with the exothermic processes, the lamellar structure of the particles has a particularly favorable effect.

In order to prevent the powder from caking in the container and during storage and then no longer being able to be suspended satisfactorily, it is proposed to add a separating agent such as ammonium phosphate, Teflon and highly disperse silica alone or in combination.

Another object of the present invention is to increase the effectiveness of the smoke screens produced.

E.g. If such a fog is generated when the wind is blowing, it is often removed too quickly from the objects to be protected. In principle, it is possible to fire several missiles with different ranges one after the other in order to lengthen the smoke screen in the horizontal direction.

This method is imprecise, and there are too large gaps between the individual fog fields.

It is therefore proposed to use several pyrotechnic nebulas arrange sentences on top of each other. Everyone has an ignition and disassembly kit. The units are separated from each other by a cutting disc. They are located in separate containers, which are ignited one after the other by a delay arranged in the cutting disc at the desired intervals.

The separate containers can contain different amounts of mist sets, in particular several pyrotechnic sets can be combined with several metal powder sets.

It is also possible to deploy the sets using a rocket. The engine fires the first sentence in flight. This is blown off and explosively distributes the fog set with good spherical characteristics on all sides. After the delay in the following sentence has burned down, it is ignited, and so on up to the first sentence.

This creates a chain of nebulae that flow into a long wall.

Ultimately, it is possible to assign the powder sets to the individual pyrotechnic sets in such a way that they are applied to the pyrotechnic fog blanket without delay or with a relatively short delay.

A known set consisting of approx. 60% perchlorate and 40% metal powder such as aluminum and magnesium can be used as the ignition charge for the powder.

• 5 bis 40 Gewichtsprozent Thioharnstoff
• 20 bis 70 Gewichtsprozent Ammoniumperchlorat
• 1 bis 3 Gewichtsprozent Aluminiumpulver mit einer Korngröße vons100 µm und
• 5 bis 30 Gewichtsprozent Bindemittel

oder der auf Basis von rotem Phosphor aufgebaut ist.A compact made of chlorine donor, metal oxide and ammonium chloride has also proven particularly useful as an optical fog set

• 5 to 40 weight percent thiourea
• 20 to 70 weight percent ammonium perchlorate
• 1 to 3 percent by weight aluminum powder with a grain size of 100 µm and
• 5 to 30 weight percent binder

or which is based on red phosphorus.

This mist set is described in DE-OS 30 31 369, as is the ignition or decomposing mixture which is preferably used for this purpose. For this purpose, reference is made to the claims.

However, the mist set can also be constructed in a manner known per se on the basis of red phosphorus (see above), which can also be processed into pressed bodies with the aid of suitable binders.

Preference is given to pressing bodies which are pressed at pressures of 500 to 1500 bar. After disassembly, these bodies still have a sufficiently small surface, so they are large enough not to burn off too quickly.

The present invention is particularly suitable for so-called proximity protection.

It is also possible to superimpose a third direction of action on the two fog components, i.e. to intensify the already existing effect against radar detection when using metal powder, or to bring it about when using other powders. For this purpose, it is proposed according to the invention to mix the glass fiber material known per se with fiber lengths of approximately 2 to 30 mm, so-called chaff.

The following example represents one of the possible combinations. Lamellar copper with a surface according to Fisher between 3200 and 16,000 cm ² / g was chosen as the powder component. This corresponds to diameters of the powder particles from 1.9 to 0.4 µm. About 0.5 percent by weight of highly disperse silica was mixed into the copper powder. The disassembly kit for this infrared mist consisted of 60 percent by weight ammonium perchlorate and 40 percent by weight magnesium / aluminum powder mixture.

The optical mist set was produced as follows: A batch of 2.2 kg PVC powder, 3.3 kg zinc oxide (dried), 2.2 kg ammonium chloride and 2.64 kg thiourea is passed through a sieve with a mesh size of 0.3 to 0.5 mm pressed and then mixed intensively. The batch is then introduced into a kneading machine and pasted for 15 minutes with 2.4 kg (based on the test specimen) of a highly viscous elastomer binder. After the kneading process has ended, ammonium perchlorate processed in the same sieving process is added in an amount of 7.26 kg. This mixture is kneaded for a further 15 minutes, then spread out on trays and subsequently dried at a temperature of 45 ° C. for 6 hours. The dry mass obtained is then comminuted in a grating machine and finally compressed to pressed bodies under a pressure of about 100 bar.

• In einem Mischbehälter werden 1,2 kg Magnesiumpulver und 0,9 kg Eisenblau gut untereinander vermischt. Zu dieser Vormischung gibt man 0,8 kg Chlorparaffin (pulverförmig), welches in 2 Liter Perchloräthylen gelöst wurde. Die Lösung wird mit der Vormischung in einem Mischer 10 Minuten gut vermengt. Danach gibt man 2,39 kg Bor amorph zu und wiederholt den Mischvorgang 5 Minuten. Als letzte Satzkomponente gibt man 4,71 kg Schwarzpulvermehl (auf 2 Komponenten-Basis, d.h. ohne Schwefelzusatz) in das Mischgefäß und läßt nochmals 10 Minuten mischen. Danach wird der lösungsmittelfeuchte Satz durch ein 1,5 mm Sieb gerüttelt und auf Trockenhorden ausgebreitet. Nach einer Trockenzeit von 5 Stunden bei 45°C kann der Satz mit einem Preßdruck von 1500 bar zu Stangen verpreßt werden.

These compacts are round and have a cross-shaped slot in the middle for receiving the primer. These disks were stacked on top of one another and arranged in the slots of the ignition charge and housed in the can. This set was made as follows:

• 1.2 kg of magnesium powder and 0.9 kg of iron blue are mixed well with one another in a mixing container. 0.8 kg of chlorinated paraffin (powdered), which was dissolved in 2 liters of perchlorethylene, is added to this premix. The solution is mixed well with the premix in a mixer for 10 minutes. Then 2.39 kg of amorphous boron are added and the mixing process is repeated for 5 minutes. As the last component, add 4.71 kg of black powder (based on 2 components, ie without the addition of sulfur) to the mixing vessel and mix again for 10 minutes. The solvent-moist set is then shaken through a 1.5 mm sieve and spread out on drying trays. After a Drying time of 5 hours at 45 ° C, the set can be pressed into bars with a pressure of 1500 bar.

This disassembling primer is ideal for a targeted, controlled disassembly of the pressed body.

The metal powder was poured into the container and the ignition charge provided for this purpose was placed in the central tube of the container. The container was placed in the can above the optical fog charge and the can was closed with a lid. The ignition head was screwed under the can and the pyrotechnic charge was ignited.

The result was an optical mist of excellent quality with a very clear IR effect. Surprisingly, this IR effect persisted considerably longer than when the powder was applied alone. If powder is applied alone, the effective times depend on the meteorological conditions of about 15 to 30 seconds, whereas the optical fog can be effective for 2 minutes and more.

With the combination according to the invention, IR effectiveness of well over 30 seconds was found.

• Fig. 1 den Aufbau eines Nebelwurfkörpers,
• Fig. 2 Preßkörper für einen optischen Nebelsatz,
• Fig. 3 den Aufbau eines optischen Nebelsatzes in einer Dose,
• _Fig. 4 eine Kombination von mehreren pyrotechnischen Nebelsätzen, und
• Fig. 5 eine Anordnung von Nebelsätzen in einer Rakete.

The explanation of the invention is supplemented below with the aid of figures. It shows:

• 1 shows the structure of a smoke nozzle,
• 2 pressing body for an optical fog set,
• 3 shows the structure of an optical mist set in a can,
• _F ig. 4 a combination of several pyrotechnic fog sets, and
• Fig. 5 shows an arrangement of nebula sentences in a rocket.

The throwing body consists of the can 5 with the ignition head 9 and cover 10. The ignition head 9 contains a powder chamber 11 and a deceleration set 12.

In the can, assigned to the ignition head 9, is initially the optical mist set 1, which consists of slotted tablets stacked on top of one another. The slots of the tablets are aligned with each other so that a crossed channel for receiving the detonating primer 3 is created. The container 7 is pushed into the can 5 via this fog set 1 and locked with the aid of a bayonet lock 13.

The container 7 is a cylindrical body with a centrally arranged tube 6, which is closed at the bottom with the aid of a film 8.

The container 7 contains the powder 2; in the tube 6 a detonating ignition 4 is accommodated. The can 5 and at the same time the container 7 are closed by the lid 10.

This structure has manufacturing advantages. However, it is also possible to assign the powder container 7 to the ignition head 9 and to layer the mist tablets over it. Since the ignition process is extremely fast, there are no significant differences.

_F ig. 2 shows the slit nebulizer tablets to be used. At the ends of the slots, the structure of the body is weakened. As shown in FIGS. 2c and 2d, the structure tears particularly easily here. The explosion of the detonating ignition charge 3, 4 can thus throw away more compact particles, which when burned up form the individual stationary sources of wind for the powder suspended therein. By the distances of the fog sources from each other there is sufficient temperature difference between the surrounding air and the quasi-adiabatically rising fog "pillars". In other words, there is a very uneven temperature profile in the fog. Conventional mists, which are created by burning or expelling them from a single source, on the other hand, have a very uniform temperature profile in which, due to the lack of potential, no thermals can develop. As a whole, this mist acts like an adiabatic bubble.

Fig. 3 shows the structure of the optical mist set 1 in a can 5 in the form of stacked tablets, in the slots of which the detonating primer 3 is inserted. The edge of the can 5 naturally extends higher than shown here and holds the powder container 7.

Fig. 4 shows the combination of a multiple charge with pyrotechnic mists.

The first fog set 1 is contained in the can 5. Above it and connected to it, the second fog set 1 is located in the separate container 7. The can 5 and the container 7 are separated from one another in an explosion-protected manner by a separating disc 14 in such a way that the disassembly of the fog set 1 contained in the can 5 does not affect those above.

A delay 15 is arranged in the cutting disc 14.

• Durch Zündung des in der Dose 5 befindlichen Nebelsatzes 1 wird dieser zerlegt und die Verzögerung 15 angebrannt. Geschützt durch die Trennscheibe 14 fliegt der im Behälter 7 angeordnete Nebelsatz 1 weiter und wird nach Abbrand der Verzögerung 15 an einer örtlich anderen Stelle zerlegt. Bedingt durch die kugelförmige Charakteristik des Nebelausstoßes fließen die Grenzen der Nebel ineinander. Dadurch entsteht entsprechend der Anzahl der ausgebrachten Einzelladungen eine Wand.

The mode of action is as follows:

• By igniting the fog set 1 located in the can 5, this is disassembled and the delay 15 burned. Protected by the cutting disc 14, the mist set 1 arranged in the container 7 flies on and is disassembled at a different location after the decay 15 has burned off. Due to the spherical characteristics of the fog the borders of the mist flow into one another. This creates a wall in accordance with the number of individual loads applied.

The combination shown in Fig. 4 shows two charges. It is of course possible to connect three or more separate throwing bodies to one another, metal powder sets also being able to be interposed.

5 shows the arrangement according to the invention in a rocket. This consists of the engine 16, the missile head 19 and a support structure shown here as three webs 17.

A metal powder set and two separate pyrotechnic fog sets 18 are shown as examples. The webs 17 can be embedded in the container walls, as can be seen in the sectional drawing. They are mounted in disks 20 and connect the head 19 to the motor 16.

The number of sentences is not limited to the three shown, but additional sentences can be added if necessary. It is particularly advantageous to install the metal powder sets mentioned above between them.

• Der Reaketenmotor 16 treibt die Rakete in Flugrichtung an. Nach vorgegebener Zeit zündet dieser den ersten Nebelsatz 1, der zerlegt wird. Durch die Stege 17 bleiben die weiteren Nebelsätze 1 an ihren Positionen und zünden jeweils nacheinander nach Abbrand ihrer Verzögerungen 15. Der Raketenmotor 16 kann dabei so ausgelegt sein, daß er bis zur Zündung des letzten Nebelsatzes 18 treibt.

The mode of action is as follows:

• The rocket motor 16 drives the rocket in the direction of flight. After a predetermined time, this ignites the first fog set 1, which is dismantled. By means of the webs 17, the further smoke sets 1 remain in their positions and ignite one after the other after their delays 15 have burned off. The rocket motor 16 can be designed such that it drives until the last smoke set 18 is ignited.

Claims (17)

1. mist projectile, consisting of a can (5) with ignition device, as well as mist (1) and detonating firing charge (3,4),
characterized,
that two or more mist sets (1) are arranged one above the other in separate, interconnected containers (7), the ignition set (3, 4) being arranged centrally in the mist sets. 2. A mist launcher according to claim 1, characterized in that the mist set (1) connected to the ignition device produces an optical and / or an IR-absorbing mist in an exothermic reaction and the mist set (1) or powder (2) with IR -absorbent properties or one or more further pyrotechnic mist sets (1) consisting of compacts, which have slits and are layered one above the other in such a way that the slits form a channel for receiving the ignition set (3, 4) and their chambers are separated by a cutting disc ( 14) are separated from one another, in which a delay piece (15) is arranged in the center. 3. mist launcher according to claim 1, characterized in that the powder (2) of the mist set (1) is arranged in a separate in the can, with a pipe socket (6) provided container (7), wherein the detonating ignition charge (4th ) is housed in the pipe socket (6). 4. Mist projectile according to one of claims 1 to 3, characterized in that the mist sets (1) are assigned different ignition sets (3, 4) and that the pipe socket (6) is closed at the bottom with a film (8). 5. mist projectile according to one of claims 1 to 4, characterized in that the powder (2) for the IR-absorbing mist copper powder, preferably lamellar copper powder with a surface area of 3200 to 16 000 cm ² / g and grain diameters of 1.9 to Is 0.45 µm. 6. Mist projectile according to one of the claims 1 to 5, characterized in that a release agent, preferably ammonium phosphate and / or Teflon and / or highly disperse silica, is mixed into the powder. 7. mist projectile according to one of claims 1 to 6, characterized in that the ignition charge (4) for the powder (2) is a known mixture of about 60% perchlorate and about 40% metal powder (Al, Mg). 8. Mist projectile according to one of claims 1 to 7, characterized in that the optical mist set (1) from a known press body made of chlorine donor, metal oxide and ammonium chloride and 5 to 40 weight percent thiourea 20 to 70 weight percent ammonium perchlorate 1 to 3 percent by weight aluminum powder with a grain size z 100 microns and 5 to 30 weight percent binder exists or is based on red phosphorus. 9. mist launcher according to one of claims 1 to 8, characterized in that the igniter (3) for the optical mist is a known disintegrating mixture of magnesium powder, black powder, oxygen donor and binder, the magnesium powder having a particle size of _ü 100 microns and that it optionally contains amorphous boron and as a catalyst an iron (II) iron (III) complex. 10. Mist projectile according to one of claims 1 to 9, characterized in that the container (7) in the can (5) is held by means of a bayonet catch (13). 11. Mist projectile according to one of claims 1 to 10, characterized in that the powder has a component acting in the radar range of e.g. Glass fibers with lengths of 2 to 30 mm (chaff) is added. 12. Mist projectile according to one of claims 1 to 11, characterized in that the wall thicknesses of the cans (5) and containers (7) for the pyrotechnic mist, the layer thicknesses of the pressed bodies in the powder chamber (11) and the igniting detonating charges (3, 4) are designed differently. 13. A muffler according to one of claims 1 to 12, characterized in that the ignition device is a rocket engine (16) and that several containers (7) are held together with the aid of a supporting structure such that the rocket engine (16) until the ignition in the direction of flight foremost set (18) remains connected to its container. 14. A smoke projectile according to claim 13, characterized in that the containers are surrounded by these supporting webs (17) which are connected to the rocket motor (16) and the rocket head (19). 15. A process for producing a mist that covers both optically and in the IR range, characterized in that an exothermic mist is burned off and a powder, preferably a lamellar metal powder, is suspended in it. 1'6. A method according to claim 15, characterized in that pressed fog sets (1) are broken down and burned and the powder is suspended in them. 17. The method according to claim 15 and 16, characterized in that, using pressures of 500 to 1500 bar compressed fog sets (1) disassembled, burned and the powder suspended therein.

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