DE2739374A1 - Training projectile with brake system - uses memory controlled alloy for spreading brake arms at given temp. - Google Patents

Abstract

The training projectile has braking system ensuring correct flight over required training trajectory. Subsequently the projectile is braked and grounded. The nose of projectile has nose part (3) made from a memory alloy. When the specified transformation temperature of memory alloy is exceeded in flight then nose part spreads to ensuring braking. Alternatively it can be used for releasing a baking mechanism. The nose part (3) is star shaped with middle part (4) with arms or segments (5). The middle part is held on the projectile nose and segments are close to the projectile walls and subsequently spread out.

Description

Training missile with emergency equipment

The invention is concerned with a training missile, in particular a training floor, with braking device.

For training bullets, but also for training rockets, for example, it is advantageous to limit the maximum range compared to that of the active or original missile, in order to be able to practice safely even on smaller shooting ranges. About the practice shooting to be carried out as realistically as possible, up to a given exercise distance, which e.g. corresponds to the maximum combat distance between the exercise and the original missile As far as possible, the trajectory and time are identical. To At the end of the training flight path, the training missile should only do one more Cover a short trajectory.

For this purpose, the shape and mass must preferably be the same as the original missile corresponding training missiles until the end of the training flight route with the normal Fly at speed and with the same precision as the original missile. Afterward the aerodynamic drag of the training missile must therefore be reliable in the further flight phase can be increased so that the training missile is decelerated quickly and gradually hits the ground in a relatively strongly curved, sufficiently short trajectory.

It is known to use a training projectile with a self-destructing charge to use, which averages a built-in timer during the onward flight phase can be triggered. The splinters that form have such a large air resistance, that they fall to the ground quickly enough. However, the disadvantage here is that the training projectile if the timer or the dismantling charge does not work Beyond the permitted maximum range and thus possibly also the shooting range flies.

This training floor is therefore unsatisfactory for safety reasons.

From the DT-AS 21 55 467 a short runway floor is also known1 the one with a hollow projectile tip in front with one as a result of the increase in temperature of the air resistance melting material closed and the bullet tip so is designed that it bursts and separates due to the air pressure in the cavity is brought from the projectile body. The remaining projectile body has a higher one Resistance and a correspondingly shortened range. This is a disadvantage the hollow design of the bullet tip, as it is resistant to mechanical stresses is sensitive. The bullet tip is therefore by means of an additional protective hood covered, which after exit of the exercise bullet from the weapon barrel through the Centrifugal force is thrown off. This training floor is undesirably expensive.

The invention is based on the object, in a training missile, in particular a training floor, with braking device, the above disadvantages to avoid and in particular to train this so that it is in the training flight phase has the trajectory and flight time of the original missile as possible, in the onward flight phase, however, is strongly decelerated, whereby on the one hand the effort for the production as low as possible and on the other hand still the perfect function should be reliably guaranteed. In particular, the exercise floor, the ungsrockete od. The like. Be designed so that the maximum allowable range also is not exceeded under unfavorable circumstances.

This object is achieved in accordance with the characterizing part of the claim 1. Memory alloys have the property that the made from them Metal parts through the respective manufacturing process a basic shape or original Shape is shaped. One then deforms these metal parts below that for each memory alloy characteristic transformation temperature, e.g. by bending or twisting, so take the metal parts to a corresponding new shape. This state is up to Transition temperature, which can be between 50 and 150 ° C, for example, stable. Becomes the transition temperature If this is exceeded, the metal parts take on more or less their original Forn on. These deformation processes are repeatable. As a memor alloy can a nickel-titanium alloy with about 5 wt% nickel and 45 wt% titanium is used as it is marketed under the name "Nitinol".

But also Merlorv alloys based on e.g. copper-aluminum-nickel, Niobium-titanium or gold-cadmium can be used.

The molded part according to the invention is preferably in its original form straight or flat, e.g. by using a plate, sheet or rod shape od. The like. Semi-finished product is separated by cutting, punching, etc. Then after that it becomes below the immersion oil temperature belonging to the respective alloy deformed, e.g. bent, so that it is adapted to the respective exercise body Takes shape. This deformation takes place preferably before the at least one Molding is attached to the training missile, but it can also be done afterwards. The molded part is preferably designed and bent so that it or individual parts is or are curved by it at least essentially only in one plane Above the transition temperature as unhindered as possible a return to the to achieve original shape. For example, one made from a disk spherical shell-shaped molded part, this should be perpendicular to its free edge ground directed incisions, so that individual relatively narrow tongue-shaped Parts are created whose curvature in the plane perpendicular to the incisions is relative is small.

The molding according to the invention is preferably in the region of the tip of the training missile, i.e. at the point where the greatest warming due to the air friction occurring during flight of the training missile. Has preferred the deformed molding has such a shape that the training missile in the training flight phase has the same drag behavior as the original missile. But it can also have a different shape, in which case with regard to the desired trajectory and flight simultaneity of other missile parameters - as e.g. in the DT-OS 25 57 293 is described - are to be changed.

The shape of the molded part is retained as long as the Uinwandluig temperature the memory logic of e.g. about 100 0C is not exceeded. Will this temperature exceeded at the end of the 4Utungsflugflugabschnitt, the molded part goes within about 0.1 s back to its original shape and takes care of the resulting Cross-section enlargement itself for the increase in resistance required for braking and / or releases a braking device by changing its shape.

The braking device can e.g. according to DT-PS 16 78 197 with a axial air inlet and lateral outflow channels, the air inlet at the tip of the bullet, e.g. by means of a correspondingly angled leg two opposing molded parts according to the invention attached to the front projectile body part is closed until the transition temperature is exceeded.

The at least one molded part according to the invention is preferably used as a flexible body formed from a memory alloy, which after appropriate heating by Air friction bends back into its original shape, unfolds, unfolds or the like. The time of this change in shape determines the deceleration and thus the maximum range of the training missile. Accordingly, the maximum range can be set e.g. by changing the U * transformation temperature of the memory alloy, Changing the heat capacity of the molded part, changing the heat transfer between Air and molded part or missile and molded part, changing the cross-section of the opened directly braking molded part and by a defined asymmetry of the as a brake body acting molded part.

In an expedient embodiment of the invention, the training is according to Claim 2 provided, according to which the molded part is designed as a braking body, the has a frustoconical shape in the deformed state. The brake body is only connected to the missile in its central area, so that the Segments after exceeding the transition temperature at least approximately into their bend back the original position can and thus the immediate Effect deceleration. According to a further proposal specified in claim 3 of the In accordance with the invention, the molded part is instead designed as a holding element, e.g. spring-loaded braking surfaces locked in the folded state and this only releases at a given point in time by changing its shape. With the corresponding Cross-sectional size in the deformed state can also be achieved by this holding element also serve as an additional brake body.

The holding element can also be designed such that it is individual Segments from which the training missile is composed, holds together and this only releases at a given point in time by changing its shape. These Then, for example, individual parts of the missile can be separated by air resistance have such an unfavorable ratio of drag to mass that their range is very short compared to the original missile.

Since the mechanical deformation of the molded part according to the invention e.g. to a truncated cone-like body at temperatures below 100 ° C as well restoring it to its original shape before mechanical deformation Exceeding the transformation temperature of the memory alloy can be repeated several times Each molded part can be tested for its functionality before the missile is assembled and, if necessary, also be checked in the assembled state. After again mechanical deformation of the molded part can then be assumed that this too if the conversion & temperature is exceeded again, the undergoes design change intended according to the invention. The functionality of the The training missile then only depends on the generation of the heat of air friction. This in turn is certain when the training missile has a certain minimum speed owns. If this is not achieved, the range of the training missile is for this reason already reduced to harmless values.

The invention is shown in the drawing in execution examples and is explained in more detail below on the basis of this.

Show it Figure 1 is a training projectile with as a brake body formed: and shown in section, figure 2a and 2b the brake body in the view and plan view in the spread state, Figure 3 is a training projectile with molded part designed as a holding element and shown in section and FIG. 4 the training floor with the holding element bent up.

The training floor 1 shown in Fig. 1 in the view has at his front end, the molded part 3 made of a memory alloy, which is fastened by means of the screw body 2 on. The molded part 3 is according to FIG. 2b, a star-like structural part with a middle area 4 and from this starting web-shaped segments 5. The segments 5 are bent before assembly below the transition temperature so that they after assembly, preferably rest in the front area of the buttock and form part of its outer surface. They preferably cover the front part of the projectile body along the entire circumference, i.e. the segments are only through one as narrow a gap as possible separated from each other. About the shape of the original bullet As close as possible, the segments 5 of the molded part 3 are in the recess 6 of training floor 1 inserted.

The frustoconical shape of the molded part 3 is retained as long as until the transition temperature of the respective memory alloy used at the end of the Practice flight distance is exceeded. The molded part 3 then goes within about 0.1 5 back to approximately its original shape, as shown in FIG. 2a, and causes direct braking so that it acts as a braking body itself.

The molded part 7 shown in Fig. 3 is, for example, a curved retaining bracket formed and with the training shot 1 at its tip by means of the screw 8 tied together. The molded part 7 engages over the front ends 9 ′ of the braking surfaces 9 in a form-fitting manner and locked this in the position adjacent to the training floor 1. The strip-shaped braking surfaces 9 are at their rear end on the training floor 1 fastened e.g. by means of a retaining ring, not shown. Fig. 4 shows the training floor 1 after the Entriegelune The molded part 7 has almost its original again Assumed shape and the braking surfaces 9 are by their own spring tension and / or bent sideways by the attacking air resistance, folded down or the like. and cause the intended strong deceleration of the training projectile 1 in the onward flight phase.

L e r s e i t e

Claims (3)

P a t e n t a n s p r ü c h e 1. Training missile, in particular training projectile, with brake device, which is not shown in the area its front end at least one molded part (3.7): made of a memory alloy is provided, but if the predetermined conversion temperature is exceeded the memory alloy changes its shape in such a way that it acts as a braking device ui'd / or a braking device releases. 2. Training missile according to claim 1, characterized in that the as a star-shaped element with a central area (4) and molded onto it Strip-shaped, lazivelle-shaped or the like. Segments (5) formed with molded part (3) its central area (4) is formed on the missile (1) and the segments (5) form part of the lateral surface of the missile (1). 3. Training missile according to claim 1, having at least one of one aerodynamically favorable braking element movable into an aerodynamically unfavorable position, characterized in that the molded part (7) as the braking element (9) in the aerodynamic favorable position positively locking retaining element is formed.