EP0204115A2 - Projectile for emitting IR radiation - Google Patents

Abstract

A throwing body for the representation of an infrared radiator, consisting of a can-shaped throwing agent container (3), an ignition disassembly sleeve (75) passing through the throwing agent container centrally, an ignition disassembly charge (35) accommodated in the ignition disassembly sleeve and burning leaves (83) with a burning layer consisting of a fire paste , is designed in such a way that a rapidly burning mass (85) is provided as a starting aid between the igniter sleeve (75) and the burning layer of the burning discs (83).

Description

The invention relates to a projectile for representing an infrared surface detector according to the preamble of the main claim. Such a projectile is known from DE-PS 28 11 016.

These missiles are used to set up so-called infrared dummy targets, i.e. to deflect missiles equipped with an infrared seeker. If, for example, the location devices of a ship determine that such a missile is approaching, then the missile is fired; which then ignites and ejects the burnt papers at a predetermined distance and height from the ship, so that the burnt papers form a slowly sinking, burning disturbing cloud which directs the incoming missile away from the ship and towards itself.

Detailed investigations of the processes have now shown that the infrared radiation of such a disturbing cloud has a very characteristic time course. The ignition of the ignition decomposition charge initially results in a "radiation flash", that is, radiation of high intensity but extremely short time, whereupon the radiation effect of the burning papers comes into play in such a way that initially a more or less steep increase (burning phase of the papers) up to a certain maximum (all leaflets burn on their total area), followed by a constant or slightly decreasing radiation, with a more or less steeply falling end flank at the time when the burning leaflets are extinguished. Between the initial radiation flash and the reaching of the radiation maximum of the focal platelets there is therefore a "radiation hole", the temporal size of which depends on the steepness of the rising edge of the platelet radiation, and is therefore a function of the reaction speed of the focal layer of the focal platelets.

Investigations have now been carried out as to whether and if so in what way the radiation hole mentioned has an influence on the protective effect of the interference cloud. It has emerged that this influence can generally be disregarded when it comes to protecting a medium-sized and medium-speed object, for example the protection of a speedboat. Throwing bodies for boats of this size class are equipped with burning papers with a burning time between 10 and 20 seconds, that is to say a comparatively quickly reacting burning layer, so that the radiation hole is comparatively short; these boats are also suitable for quick evasive maneuvers due to their maneuverability.

On the other hand, when it comes to protecting very fast-moving objects, especially aircraft, the radiation hole mentioned can lead to a reduction in protection, because the distance between the aircraft and the radiation cloud increases extremely quickly. Although it is now possible to shorten the radiation hole by increasing the reaction speed of the burning layer of the burning papers, for example to a -sufficient burn time of 5 seconds, this did not achieve fully satisfactory results, especially not because of the high relative speed of the Burning papers in relation to the air there is a delay in the burning process even with fast-reacting burning layers.

On the other hand, the radiation hole mentioned has a disadvantageous effect on the protection of very large and slowly moving objects, such as ships of considerable size, if for a completely different reason than in the case of the aircraft mentioned above. In order to protect large ships, a very early detection of the approaching missile is necessary, on the one hand because the maneuvering speed of such ships is low, and on the other hand because the missile can only be deflected if both the ship and the neighboring interference cloud are in its search field appears, which is only the case if the missile is still far away from the ship. However, the requirement of comparatively early formation of the radiation cloud means that the radiation time of the cloud must be long, so that the burning leaves have a burning time of, for example, 30 to 40 seconds. The latter is only possible if the reaction speed of the burning layer is very slow, with the result of a very slow burning process, which leads to such an elongation of the radiation hole that there is no longer any guarantee for the timely deflection of the missile if immediate measures have to be taken , the incoming missile is recognized very late. This disadvantage with immediate measures is independent of the size and speed of the object to be protected.

The object of the present invention is therefore to improve the throwing body of the type mentioned at the outset in such a way that the explained radiation hole of the resulting radiation cloud is considerably shortened, both in the case of combustion layers short as well as long and very long burning times for burning layers. The solution to this problem results from the characteristics of the characterizing part of the main claim.

According to the invention, therefore, an ignition aid mass is switched on between the igniter charge or igniter sleeve and the burning leaves, that is to say a fast-reacting mass which, on the one hand, emits high-intensity infrared radiation during its combustion and thus, so to speak, extends the flash of the igniter charge, and on the other hand extends the layer of fire Firing leaves ignited so extensively that their radiation rising edge becomes very steep. The prolongation of the radiation flash has an effect on burning papers with burning layers of any reaction speed (fast, medium, slow) with regard to the largest possible ignition, and this also in the case of a high relative speed between the burning papers and the ambient air - (prevention of the blow-out effect). However, this significantly increases the range of application of the throwing bodies, both with regard to the use for protecting very fast objects ((aircraft) and very large objects (large ships), as well as generally for the implementation of immediate measures.

A particularly expedient development of the invention is characterized in claim 2. It should be pointed out that in the case of burning layers which react particularly slowly, that is to say burning sheets with extremely flat rising flanks, it is advisable to replace part of them with rapidly burning sheets so as to bridge the radiation hole. With this measure, it is also possible to represent an apparent target with a long service life (30 to 40 seconds) that initially has a high radiation power, which then drops to a lower level after a few seconds (for example 5 to 10 seconds) and then this level maintains for a long time. In addition, however, the embodiment according to claim 2 also provides advantages in the case of immediate measures. Especially with such a measure, it is necessary that the dummy target shines with the highest possible intensity immediately after initiating the fault measures, because in such a case the seeker has already switched to the target and therefore the dummy target must radiate much more than the actual one Aim to pull the seeker head away from the latter. This radiation behavior is in turn made possible by a mixture of fast-burning papers (high radiation intensity) and slow-burning (low radiation intensity) papers.

Further expedient refinements of the invention result from subclaims 3 to 10.

In the drawing, an embodiment of the invention is shown, the single figure showing the throwing body in longitudinal section.

In detail, the figure shows a contact head 1 with a charge chamber in which, in the ready-to-operate state, there is an ejection charge 15, in which a squib 17 is embedded. The charge chamber is closed on the bottom part of the contact head 1 with a screw cap, which has window-like predetermined breaking points and a web-shaped abutment for a spacer of a shooting cup. An ignition delay set 31 is arranged in the head part of the contact head 1 and connects the charge chamber to the inside of a throwing agent container 3. The ignition delay set 31 is screwed into the head part of the contact head 1 via a threaded sleeve. In the jacket of the charge chamber there are passages which connect the squib 17 via sealed wire lines and via connecting pins to contact rings arranged in the outer jacket of the contact head 1. Screws 45 can be seen in the contact head 1, the bores of which are closed flush with cover caps 109 with the bottom part of the contact head 1. The screws 45 lead into a fastening plate 71 arranged in the bottom 29 of the throwing agent container 3 and thus firmly connect the throwing agent container 3 to the contact head 1.

The fastening plate 71 is arranged in a tightly closing manner in the bottom of the throwing agent container 3 via an O-ring 113. The contact head 1 is made together with the screw cap, including its other components, by injection molding from polystyrene.

At the head of the throwing agent container 3, a cover 5 is arranged via a corresponding flange. Throwing agent container 3 and lid 5 of this throwing agent container 3, including the fastening plate 71 (or the base, which is reinforced as a fastening plate), are made of aluminum. The wall thickness of the throwing agent container 3 and the material thickness of the lid 5 are approximately 0.25 mm.

An ignition disassembly unit 33 is inserted in the interior of the throwing agent container 3 in the mounting plate 71. This ignition disassembly unit 33 consists of a sleeve 75 which contains an ignition disassembly charge 35 and which has an inwardly flanged edge 77 at its end located in the mounting plate 71 a cover disk 79 engages, via which the sleeve 75 by means of a perforated screw 81 and an annular seal 115 closes tightly in the mounting plate 71 on the bottom 29 of the litter telbehälters 3 is attached. The bore in the cover disk 79 is covered with a glued-on film 119, preferably a tin film, and this thereby closes the ignition disassembly kit 35 with respect to the ignition delay set 31. The igniter disassembly passes through an igniter core 37 made of nitrocellulose powder tubes over its entire length. This powder tube preferably has a diameter of 1.3 mm and a continuous inner hole of 0.2 mm in diameter. At a distance from the sleeve 75 of the ignition disassembly unit 33 to the wall 41 of the throwing agent container 3, a throwing agent 73 is arranged in the interior of the throwing agent container 3, which is circular sector-shaped leaflets 83 with burning layers. These circular sector-shaped leaflets 83 are thus arranged in the interior of the throwing agent container 3 at a distance around the sleeve 75 of the ignition disassembly unit 33 in a layered manner. The sleeve 75 of the dog dismantling unit 33 is made of aluminum just like the throwing agent container 3 and its cover 5 and its fastening plate 71. Sleeve 75, throwing agent container 3 and lid 5 each have a wall thickness of approximately 0.25 mm.

A second sleeve 84, which has an extremely thin wall thickness, is provided between the igniter sleeve 75 and the fuel discs 83, to be precise after these. The annular space between the two sleeves 75 and 84 is filled with an ignition aid compound 85, specifically with loosely poured red phosphorus.

The operating sequence of this litter _k örpers corresponds to that of the known throwing body, with the exception that this ignited during the ignition of the Anzündzerlegersatzes 35, the igniter mass 85 which emits considerable during their brief burn-infrared radiation strength and at the same time the internal leaflets 83 over a large area ignites. This large-area ignition of the burning discs 83 results from the fact that the firing of the ignition aid mass 85 forms a fireball around the throwing body, which the burning discs 83 fly through. The burning sheets 83 therefore quickly catch fire over a large area and this also when the burning layer is very slow to react, that is to say, for example, passivated or covered with a passivation layer.

With regard to the above-mentioned uniform, large-area ignition of all burning leaves, it also plays an essential role that the ignition disassembly set reacts uniformly over its entire length, so that the ignition aid can be effective evenly all around and over the entire length. This is promoted by the ignition core made of nitrocellulose powder, which is centrally located in the ignition disassembly kit, which has a stabilizing effect with regard to rapid combustion due to its easy flammability, the high rate of combustion and the release of gas during combustion. Without this burn-off stabilizer, there could be a risk of fluctuations in the reaction speed which can be caused in the course of storage as a result of an uneven compression of the batch, these uneven compressions being caused, for example, by shaking during transport.

By coordinating the quantity and reaction speed of the ignition aid mass 85 and the reaction speed of the burning layer of the burning discs 83, optionally using a mixture of slowly and rapidly burning discs, it is possible to significantly shorten the radiation hole after the flash of ignition igniter 35 or even completely to bridge, regardless of the total burning time of the dummy target. All cases of property protection mentioned at the beginning can thus be taken into account.

Of course, the invention is not limited to the exemplary embodiment shown, but numerous modifications are possible compared to it. For example, the second sleeve 84 is not absolutely necessary; the. Ignition aid mass 83 can also be filled into the annular space between the sleeve 75 and the stack of fuel sheets. Another possibility is to extend the fuel discs 83 to the sleeve 75 and thus to drop the annular space, in which case the discs themselves are dusted with the ignition aid compound 83 or this is applied to the discs as the top layer. Finally, it is also possible to use an ignition aid compound other than red phosphorus, but this is preferred because it is usually also part of the burning layer of the leaflets 83.

Claims (10)

1. Throwing body for the representation of an infrared surface radiator consisting of an electrically actuated contact head, a can-shaped throwing agent container arranged thereon, closed with a lid, an igniter sleeve which is connected to the contact head and which penetrates the throwing agent container centrally, an igniter charge accommodated in the igniter sleeve for igniting a arranged around the igniter sleeve, combustible throwing agent and for disassembling the wall of the throwing agent container, and out of the throwing agent constituting burning leaflets with a burning layer consisting of a fire paste, characterized in that a rapidly burning mass (85) is provided as a starting aid between the igniter disassembly sleeve (75) and the burning layer of the burning leaflets (83). 2. Throwing body according to claim 1, characterized in that the burning leaves (83) have different burning speeds. 3. Throwing body according to claim 1 or 2, characterized in that the ignition aid mass (85) is red phosphorus in powder form. 4. throwing body according to one of claims 1 to 3, characterized in that the ignition aid mass (85) is dusted onto the fuel discs (83) or applied as a layer to these. 5. throwing body according to one of claims 1 to 3, characterized in that between the igniter sleeve (75) and the fuel discs (83) a concentric, substantially over the entire length of the igniter sleeve (75) extending annular space and this with the ignition aid -Mass (85) is filled. 6. throwing body according to claim 5, characterized in that the igniter sleeve (75) is concentrically surrounded by a thin-walled sleeve (84), the gap between the two sleeves (75, 84) being filled with the ignition aid compound (85). 7. throwing body according to claim 2, characterized in that at least two groups of burning leaves (83) are provided, the one group being provided with a rapidly reacting, the other group with a comparatively slowly burning burning layer. 8. throwing body according to claim 7, characterized in that the burning layer of the group of burning leaves (83) slow response time has an at least partially passivated burning layer. 9. throwing body according to claim 8, characterized in that the passivation is effected by addition of aluminum hydroxide in burning leaves (83) based on red phosphorus. 10. Throwing body according to one of claims 1 to 9, characterized in that the igniter sleeve (75) contains a nitrocellulose core (37) as a burn-off stabilizer.

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