EP0173008A2 - Method for the protection of infrared radiating targets, especially ships, from missiles equipped with infrared homing guidance heads - Google Patents

Abstract

The method involves firing from a launcher installed at the threatened target a projectile charged with a combustible projecting agent, destroying the projectile and at the same time igniting and dispersing the projecting agent to form an infrared simulated target cloud alongside the target and in the range of the optics of the homing guidance head, the cloud having a higher infrared radiation intensity than that of the threatened target, characterised in that several projectiles are successively fired and destroyed, with the propelling agent in them ignited and dispersed, at such intervals in time and space that a chain of successive further new infrared simulated target clouds, each following on from the one before, is produced and thus a simulated target shifting constantly further away from the threatened target is formed. This method is preferably carried out using a single launcher charged successively with several projectiles, for example with five to nine projectiles, preferably with seven projectiles.

Description

It is already known that infrared radiation targets, such as ships, can be protected from missiles equipped with infrared guidance seekers by setting an infrared dummy target next to or above the target, but in the area of the optics of the infrared guidance seeker head has a higher infrared radiation power than the threatened target. Infra-red shining target clouds are particularly suitable for this purpose, for example by firing a missile loaded with a flammable throwing agent, namely so-called pyrotechnic flares

from conventional throwing cups, disassembling the throwing body at a certain distance from the target and simultaneously igniting and distributing the burning throwing agent. In addition to these fictitious target clouds, there are also infrared torches. However, these are only point emitters and therefore less suitable for deception than the apparent target clouds, which represent large-volume and only slowly sinking area emitters with high radiation power. The latter are therefore preferred for initiating fault measures.

The formation of a single infrared target cloud is generally sufficient as a fault measure for smaller targets, such as S-boats, but for larger targets, such as frigates, there are disadvantages and uncertainty factors that at least partly relate to the functioning of the infrared - Steering seekers are attributable.

These search heads have optics which at the beginning of the so-called search phase, which usually begins at a distance of about 10 to 15 km from the target, have relatively large aperture angles, so that they have, for example, a search range of about 3000 to 5000 m in azimuth and about 300 to Can measure 500 m in elevation. After detection of the When the missile approaches the target, the steering seeker switches to the target, which is also known as lock-on, and with this process the viewing angle of the optics of the steering seeker head is greatly reduced, both in azimuth and in elevation. At a distance of approximately 5 km to 8, usually takes place bridging onto the target in the one detected by the search window of the _L enksuchkopfs range is then only about 100 meters in azimuth and about 50 m in elevation. This area then becomes smaller and smaller as the missile approaches to the point of impact. The infrared mock target cloud to be deflected for the missile may therefore only be about 40 to 50 m laterally from the center of radiation of the target and only about 25 to 30 m above the boat, so that it is still from the already reduced viewing angle of the optics of the infrared steering seeker head is detected. In an S-boat in such a case, the new radiation center of gravity formed by the infrared mock target cloud and the S-boat then lies just outside the boat, and it shifts more and more towards the mock target as the missile approaches as the mock target cloud has a much higher infrared radiation power compared to the actual target. In the case of small ships, such as S-boats, the missile is therefore generally fully deflected by the formation of such a single apparent target cloud.

The situation is different in the case of larger ships, such as a frigate, which is normally about 120 m long. Here, the apparent target to be formed must still be in the area of the ship, so that it can still be detected by the optics of the infrared missile guidance head of the missile that is already connected to the target. The missile will be deflected by the apparent target formed in the best case only so far that it flies over the threatened ship only more or less closely. In such a case, however, there is a risk that the missile via its proximity fuse to the Ex plosion is brought, the sensitive deck structures, such as antennas, sensors and the like, being destroyed. This would result in a severe impairment or even a complete loss of the operational capability of the ship.

As the size of a ship increases, its mobility also decreases. For example, S-boats can also perform evasive maneuvers after setting the infrared dummy target due to their lightness and maneuverability, thus increasing the distance to the dummy target. In the short time available, however, larger ships can no longer perform such maneuvers, so that they are practically solely dependent on the apparent targets set as a protective measure. This generally applies to ships with a water displacement of around 600 t, and thus already to corvettes.

The above explanations show that although the conventional formation of an infra-red target cloud, smaller targets, for example S-boats, can be adequately protected against missiles equipped with infrared guidance heads, but not larger targets, for example ships such as corvettes and especially frigates.

Based on the known formation of infrared shining target clouds for the protection of infrared radiation targets, in particular ships, the object of the invention is therefore to create a new method of this type, by means of which the respective targets can be protected better and more reliably Above all, sufficient protection of larger targets, in particular larger ships, can be achieved, and this object is now achieved according to the invention by the method which is defined in claim 1. Preferred embodiments of this method can be found in subclaims 2 to 6.

The essential element of the invention therefore consists in such an application of a conventional surface radiator that at the beginning of the interference maneuver as close as possible to the target, for example to the ship to be protected, a first infrared target cloud that can be detected by the optics of the infrared steering seeker head is formed, whereupon with such a temporal and spatial offset, a subsequent new apparent target cloud is formed in such a way that at least the previous apparent target cloud retains its radiant power until the new apparent target cloud has fully developed its radiant power, so that, at least over a short period of time, an effect-related transition or better said there is an overlap between the two successive infrared target clouds. This creates a chain propagating from chain link (previous dummy target cloud) to chain link (subsequent dummy target cloud) from a further new dummy target cloud, which is continuously detected by the optics of the infrared steering seeker head, so that the missile is increasingly pulled further away from the threatened target. Depending on the time sequence and the number of missiles fired, larger ships can thus be protected from missiles equipped with infrared guidance heads. The overlap times can of course also be longer, so that under certain circumstances not only two but several clouds burn at the same time and develop their effect as a false target.

The process according to the invention can be carried out in such a way that the throwing bodies required for forming the propagating chain of infrared dummy targets are fired from a number of launching tubes, each loaded with one throwing body, in order, under command control, at ever increasing distances, but preferably one with several Throwing bodies in a single loaded and also command-controlled launch tube is used. The use of such a single _A -shot tube, in which the individual projectiles are stacked Arranged one behind the other has the advantage, among other things, that there is a substantial saving in weight and space for the installation required for firing, which is particularly important because warships are generally very limited in terms of their space and weight capacity and usually up to anyway extreme limit are busy. The main advantage of using a single launch tube is, however, that the length of the firing of the individual projectiles results in an increasingly longer guidance in the launch tube. The result of such a longer guidance is both a higher accuracy as well as a higher acceleration and an associated increase in flight distance.

Firing from a single launch tube therefore essentially achieves two things. The ever-increasing acceleration when firing the individual throwing bodies enables, on the one hand, a very substantial amount of the higher amount of propellant charge otherwise required for the increasing distance to be increased. This means a reduction in recoil and thus the load on the weapon and ammunition, which in addition to the resulting weight saving is also associated with constructive and cost advantages. On the other hand, the scatter that increases with the flight distance is compensated for by the increasing accuracy due to the increasingly longer guidance in the launch tube. In this way, a propagating chain can be optimally formed from successive infrared-shining target clouds, which have a relatively close distance from each other with effective interlocking and result in a relatively cleanly aligned straight line.

For the protection of larger ships, such as frigates, it is generally sufficient if one or five to nine, preferably them, are used in succession according to the method of the invention ben, missile shoots, preferably using a single launch tube for this purpose, which is loaded with such a number of missiles. If one does not use a single launch tube for firing the required row of individual projectiles, then the above-mentioned, special additional advantages naturally do not arise, and in such a case, namely when using multiple individual launch tubes, appropriate structural measures must be taken to ensure that that the clean chain that is essential for the success of the method according to the invention results from successive further new infrared target clouds.

The throwing bodies to be used, including the throwing means contained therein and the launching tubes required for firing them, can be constructed in the usual way. It is essential, however, that the throwing agent contained in them results in an infrared shining target cloud with an infrared radiation power that is higher than that of the threatened target, and that the throwing agent providing this radiation power has a relatively long and defined burning time and a has a low sink rate. As a result of the propagating chain of successive further infrared dummy target clouds required to achieve a clean effect, the further new infrared dummy target cloud must be formed in a time sequence which results in a sufficient overlap of the burning time with the respective previously formed infrared dummy target cloud. Without such a burning time overlap, it could happen that the missile's steering seeker head, already set to the apparent target, either swivels back to the threatened target if it is still within its viewing angle, or that the entire search maneuver starts again after resetting to the search phase.

For the reasons set out above, the further new infrared sham target cloud are therefore formed under a time sequence which results in a burning time overlap of at least 1 to 2 seconds with the previously formed infrared sham target cloud. Longer overlap times do no harm. As a rule, however, two thirds of the burning time of the individual dummy target clouds should not be exceeded, because otherwise more than three clouds will shine at the same time, thus blurring the impression of the target target migrating away.

The optimal burning time and thus the service life of a single target, taking into account a sufficient duration of the entire fault measure and the required overlap time, is between 9 and 15 seconds. The firing time of the throwing medium must therefore be at least 9 seconds and should not exceed 15 seconds. In addition, its rate of descent must be very low, because otherwise the distance to the next cloud may be so great that the subsequent cloud is no longer detected by the infrared guidance seeker, or at least the two clouds are so far apart that they no longer represent a uniform apparent target. These conditions are met by a flammable throwing agent as described in BE-PS 874 835.

The time sequence under which the individual missiles are fired depends not only on the burning time of the individual dummy targets, but also on the speed and distance of the missile to be deflected and the size, direction and speed of the object to be protected. Normally, this time sequence is chosen such that a new, new, infrared target cloud is formed at the earliest every 3 and at the latest, every 13 seconds as part of the propagating chain of new infrared target clouds. In exceptional cases, however, a shorter time sequence is possible, for example down to a second or less. Such a short succession of times may be required if an approaching missile is recognized too late, so that long time sequences are no longer possible. In the most extreme case, therefore, all throwing bodies are fired immediately one after the other, but then only an elongated path is formed from apparent target clouds that blossom in short succession, and thus practically no more away migrating apparent target. However, since the missile controls the center of radiation, which is formed by the actual target and the apparent target, it is still deflected to such an extent that the target is no longer or only slightly endangered in such a case.

The essential element of the method according to the invention consists, according to the above statements, that, in contrast to the known methods for protecting an infrared radiation target against missiles equipped with infrared guidance seekers, not only a single infrared target cloud or several, but not functionally connected Infrared target clouds form, but in succession with such a temporal and spatial offset generates a propagating chain of successive and functionally connected infrared target clouds that results in a fake target constantly moving away from the threatened target. For this purpose, conventional throwing bodies, launch systems and other devices required for this purpose can be used, which, however, have to be redesigned if necessary. A device that is particularly suitable for this purpose emerges from the patent application with the internal file number BU 18, filed simultaneously with this application by the same applicant.

The start of the interference maneuver to be initiated by the method according to the invention and also the time interval between the individual launches are normally determined by a computer by entering the above-mentioned data. All of this must be designed so that each the previous sham target cloud burns at least for a certain time and thus unfolds its effect, while the subsequent new infrared sham target cloud achieves its maximum effectiveness. An at least brief, effective overlap is therefore required between the two clouds, which must be at least about 1 to 2 seconds. The successive infrared shining target clouds are usually about 15 to 25 m apart in their focus. The apparent target therefore moves about 15 to 25 m further away from the threatened ship per shot missile. A prerequisite for effective protection is that the dummy target formed does not go out at any time during the necessary protective measures and, of course, must not be too far away from the previous dummy target, since it would otherwise no longer be in the angle of view of the infrared missile seeker head of the respective missile and thus away from it is no longer recorded. If the dummy target goes out, the infrared steering seeker would swivel back to the actual target if it was still within its respective viewing angle. The same happens if there is a gap in the course of the interference maneuver. The apparent target that lights up too late could then already be outside the view of the optics of the infrared steering seeker head, as a result of which the entire deflection maneuver would lose its effect. Of course, when using a simple, namely not position-stabilized launch tube, the individual projectiles can only be fired from the exact same position of the ship, since a precise line of consecutive apparent targets must be formed, which cannot be achieved without appropriate control. Depending on the size of the ship and the extent of the swell, different firing times for the individual projectiles can also result for a rolling ship. In contrast, if the launch is controlled by calculation, such irregularities can usually be automatically compensated for.

Claims (6)

1. A method for protecting infrared-radiating targets, in particular ships, from missiles equipped with infrared guidance seekers, whereby in addition to the target and in the area of the optics of the guidance seeker, by launching a missile loaded with a flammable throwing agent from a target on the threatened target Installed launch tube, disassembly of the throwing body and simultaneous ignition and distribution of the throwing agent forms an infrared mock target cloud with higher infrared radiation power than the threatened target, characterized in that one shoots several throwing bodies in succession with such a temporal and spatial offset and with ignition and distribution of the throwing means contained therein, that a chain propagating from the respective previous dummy target cloud is formed from successive further new infrared dummy target clouds and thus a dummy target is constantly moving away from the threatened target. 2. The method according to claim 1, characterized in that one uses a single launch tube loaded with several throwing bodies in series. 3. The method according to claim 1 or 2, characterized in that one after the other five to nine projectiles, preferably seven projectiles, fired or used for firing a single launch tube loaded with such a number of projectiles. 4. The method according to any one of the preceding claims, characterized in that the respective further new infrared target cloud is formed under a time sequence which results in a burning time overlap of at least 1 to 2 seconds with the respective previously formed infrared target cloud. 5. The method according to any one of the preceding claims, characterized in that throwing bodies are used, the throwing means of which, when ignited, produce an infrared mock target cloud with a burning time of at least 9 to a maximum of 15 seconds. 6. The method according to claim 5, characterized in that one shoots the throwing body under a sequence of times and disassembled with ignition and distribution of the throwing agent located therein, that at the earliest after 3 seconds and at the latest after 13 seconds, another new infrared target cloud as part of the propagating Chain of new infrared target clouds is formed.