EP0062750A1 - Method for the dispersal of subcharges from a carrier missile - Google Patents

Abstract

When distributing submunitions such as mines, bomblets or daughter missiles or other active components by means of a carrier missile, a minimal collision probability should be aimed for during the distribution process. For this purpose, a double ejection method is provided, in which the individuals (5) of the submunition are housed in a number of special distribution units (2), which in turn are used as secondary bodies for several in the carrier missile. With primary ejection over the target area, the distribution units (2) are ejected, stabilized at a distance from the carrier body and, unlike this, e.g. delayed by means of a parachute (4), so that the trajectories diverge and a collision is thus ruled out. The submunition (5) is then ejected from the distribution units (2) in the secondary outlet.

Description

The invention relates to a method for distributing submunitions according to the preamble of the claim

The distribution of submunitions using carrier missiles is generally known. The submunition can be mines, bomblets, daughter levels, interfering bodies or the like. Rockets in particular are considered as carrier missiles, but also grenades, for example. In the previous technical solutions, the warheads of the launchers or the grenades above the target area are generally dismantled in various ways and all individual bodies or individuals of submunition are released immediately.

The increasingly high tactical and technical demands placed on the various types of submunition in recent years have led to increasingly complex designs Electronics and electromechanical sensors. These submunitions are inevitably more susceptible to interference from high mechanical loads, as they occur with the known distribution methods.

From DE-OS 21 53 994 it is also known to arrange submunitions or general ejection bodies in the warhead of a missile, which is provided with a special distribution unit. This distribution unit has a payload carrier plate with a plurality of pivotally attached ejection tubes containing the ejection bodies, which are spread apart before being distributed. In order to achieve a circular distribution of the ejection bodies on the ground, the distribution unit can be braked before the release of the ejection bodies by additional braking measures, for example by means of a brake parachute or by airbrakes, so that it sinks vertically downwards. The distribution unit can still be connected to the remaining rocket or can also be separated from it and transferred to the vertical path on its own.

However, as has been shown, even with this method it is still not possible to achieve a distribution that is satisfactory under all circumstances. If the entire carrier missile is braked, an undesirably large amount of effort is required for the braking measures. If the distribution unit is separated from the rest of the missile, it has been found that during the further movement of the two bodies there can be collisions between them, which prevent the defined release of the submunition or ejection body and lead to undesired additional loads. The consequence of this can be a reduced functional reliability of the submunition.

The invention has for its object, in particular the to avoid the above disadvantages, ie to carry out a method for distributing submunition in accordance with the preamble of claim 1 in such a way that collisions and other undesirable loads and thus a reduction in the functional reliability of the submunition are at least largely avoided.

This object is achieved in accordance with the characterizing part of claim 1. As a result of the defined ejection of the one or more distribution units from the carrier missile after reaching the ballistically determined disassembly point above the target area, such a large distance is generated between the distribution units and the remaining part of the carrier missile that collisions between the distribution units and the carrier missile and the resulting disturbances in the distribution of submunitions on the ground can be reliably avoided. The distribution unit is preferably ejected in the direction of flight of the carrier missile. The defined guidance during the ejection movement can e.g. can be achieved in that the distribution units designed as cylindrical or tubular bodies are guided like bullets in corresponding tubular ejection devices of the carrier missile. In this case, the distribution units can be ejected from individual tubes or in a row one behind the other and / or next to one another, in each case in an ejection tube, if necessary via a sabot. Guided tours in the manner of start rails are also possible.

The distribution units are provided with aerodynamic stabilization devices, for example guide surfaces, in order to avoid undefined flight movements. The at least one distribution unit, which initially moves at a distance from one another on the same trajectory, and the rest of the carrier missile are then delayed differently ballistically. For example, has the rest Carrier missiles have a much lower mass than the distribution unit, so that alone it can be braked sufficiently more and thus deflected downward from its original trajectory. However, it is preferably provided that the distribution unit is provided with a braking device which has a stabilizing effect at the same time, so that the distribution unit is decelerated more and is thereby deflected downward and the carrier missile largely flies over the distribution unit on the ballistic path of the original missile. The distance of the distribution unit from the carrier missile generated by the defined primary ejection from the carrier missile and its braking are coordinated with one another in such a way that the distribution unit nevertheless remains at a sufficient distance from the carrier missile when re-approaching due to the braking. Subsequently, the individuals of the submunition can be expelled from the distribution unit and thus released for individual distribution in the secondary output. In this way, possible collisions of the remaining parts of the carrier missile with the distribution unit and also with the submunition are excluded and reproducible ballistic conditions are achieved.

Due to the primary and secondary output according to the invention, also called double output, in heavier carrier units, i.e. Missiles with a larger number of submunition individuals achieved further advantages, which are explained in more detail below.

With the known distribution methods, based on the individual shot, a random distribution of the individuals of the submunition on the ground is achieved, which approaches the uniform distribution in the case of a small number of individuals and the Gaussian distribution in the case of a large number of individuals.

If the carrier missiles are fired in series under the same firing conditions, there is also a Gaussian distribution for the carrier ammunition, which is superimposed on the random distribution related to the individual shot. With a large number of individuals in a carrier unit, this superimposition does not result in optimal area coverage, since two Gaussian distributions overlap. This is generally only achieved if the individuals of the submunitions related to a carrier unit are distributed almost equally.

According to the invention, in the case of heavier carrier units, the submunition individuals are accommodated in a plurality of distribution units which are arranged next to and / or one behind the other as secondary bodies in the carrier missile. Their number is small in relation to the total number of individuals per carrier unit. As a result, approximately the same distribution of the distribution units per carrier missile is achieved in the primary ejection according to the static laws, which has an expansion corresponding to the ejection height. If the number of individuals per distribution unit is now also low, a more or less perfect uniform distribution is achieved with secondary output, based on the individual distribution unit. Since the second ejection point is lower than the first, the less extensive uniform distribution of the individuals per distribution unit advantageously overlaps the equal distribution of the distribution units to a uniform distribution of all individuals of a carrier missile.

In the case of carrier missiles with a larger number of submunition individuals, the known distribution methods also cause the individuals to accumulate at the release point when the submunition is released immediately from the carrier missile. This increases the likelihood of collision between individuals and significantly increased with parts of the disassembled carrier missile. This disadvantage is also avoided if the submunition is accommodated in several distribution units, the number of which is correspondingly smaller than the number of individuals.

The individuals of the submunition are preferably arranged one behind the other in a stack or column-like manner in the distribution unit. Depending on the direction of ejection from the distribution unit, they are furthermore preferably oriented in such a way that they do not have to roll over after being ejected, for example, in order to assume their intended position during the flight. This secondary ejection from the distribution unit can take place in its flight direction. However, according to claim 2, the individuals of the submunition are preferably ejected from the distribution unit against the direction of flight or these are withdrawn to the front, so to speak. The distribution unit is additionally accelerated in the direction of flight, while the submunitions are decelerated. Due to the generally much smaller mass of the distribution unit compared to the submunition, the speed of the distribution unit is greatly increased, so that a clear distance is again generated between the distribution unit and the submunition. Due to the subsequent different ballistic delay, the trajectories of the two components then diverge in such a way that a collision is not to be feared in the further course of the distribution process.

Another disadvantage of the previous distribution methods is that when the submunition is released, the flight speeds are generally too high immediately afterwards. The associated mechanical loads, which occur abruptly when released, can endanger the electronic and electromechanical components of modern submunitions and thus their function further reduce reliability in addition to the risk of collision. According to a further proposal of the invention specified in claim 3, it is therefore provided to brake the distribution units before the secondary output to such an extent that the submunition can be ejected without risk of damage due to the stresses resulting from the air flow.

In the case of carrier missiles flying at supersonic speed, the double ejection according to the invention also offers the possibility, according to claim 4, of achieving an optimal deceleration of the distribution unit on the one hand and of the individuals of submunition on the other hand, for example by the distribution unit is slowed down with a brake parachute designed for supersonic speed, while the individuals e.g. with brake parachutes designed for subsonic speeds are so delayed that they do not exceed an intended impact speed on the ground. As a result, a directed impact on the ground is achieved with correspondingly defined loading directions for which the submunition can be designed. The random distribution of the submunition individuals can be e.g. can be extended to a larger area through asymmetrical openings in the brake parachutes.

The sequence of the method according to the invention is shown by way of example in the drawing in four different phases and is explained in more detail below with reference to these.

1 shows the primary ejection after the carrier missile 1 with the sleeve-shaped distribution unit 2 containing the submunition has reached the ballistic ejection point above the target area. The output of the distribution unit 2 takes place after an ignition pulse from a timer or to the ground appealing distance igniter by means of a pyrotechnic discharge charge. The ogive 3 is blown off beforehand or simultaneously with the ejection. The distribution unit 2 stabilized by means of the supersonic screen 4 and, like the carrier missile 1, moves on a defined trajectory is shown immediately after the ejection process, ie still close to the carrier missile 1.

In the course of the further movement, the distance between the two bodies is initially increased until the retarding effect of the parachute 4 predominates and the distribution unit 2 swings into its own flight path according to FIG. 2. The remaining carrier missile 1 flies over the distribution unit at a sufficient distance so that collisions are excluded.

3 shows the secondary output after the distribution unit 2 is braked to subsonic speed. The submunition, here five mines 5, is ejected against the direction of flight again with the aid of a pyrotechnic charge from the distribution envelope 2 ″ closed at its front end 2 ′ after a predetermined delay time from the primary emission. The time delay can be based on pyrotechnic, mechanical or electronic The brake parachute 4 is also separated.

The mines 5 arranged in the distribution shell 2 ″ as a dense stack with their subsonic parachute 6 are separated by the strong successive braking and finally float stabilized and braked according to FIG. 4 in approximately equal distribution to the ground. As a result of asymmetries in the braking devices 6 and in the secondary discharge present elevation, the distribution of the mines 5 on the ground can be influenced.

Claims (4)

1. A method for distributing submunition, in which the individuals of the submunition accommodated in at least one distribution unit of a carrier missile are released at a predetermined time, characterized in that the at least one distribution unit is ejected from the carrier missile in a defined manner by being during the ejection movement is guided therein, and is kept at a stable flight position at a distance therefrom, and that the carrier missile and the distribution unit are decelerated differently, so that the flight paths of both diverge, and finally the individuals of the submunition are ejected from the distribution unit. 2. The method according to claim 1, characterized in that the submunition is ejected against the direction of flight of the distribution unit from this. 3. The method according to claim 1 or 2, characterized in that the submunition is only ejected when the distribution unit is braked to a speed which can be expected of the submunition. 4. The method according to claim 3, characterized in that the distribution unit is braked before the ejection of the submunition with the aid of a braking device for the supersonic range, preferably to subsonic speed.

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