NL8200213A - EXERCISE PROJECTILE. - Google Patents

Description

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Practice project

The invention relates to a training projectile which is stabilized by its own rotational speed and which contains a conical nose, a cylindrical intermediate part and a tailpiece and which projectile is provided with braking means for reducing the said rotational speed after it has been launched.

For military exercises, for economic reasons, normal live ammunition is usually replaced by specific practice ammunition. Such practice ammunition is often simpler than normal live ammunition in order to reduce firing costs. In order to allow military personnel to be trained in normal shooting fires, it is important that the ballistic characteristics of the. Practice ammunition virtually matches that of the one in place. set live ammunition. As a result, the maximum fire or firing range of the practice ammunition then corresponds to the maximum fire range of the relevant live ammunition. However, this also means that the military exercises must take place on the few very large firing ranges and that relatively large areas must be closed in order to allow the firing.

As a result, a new type of practice projectile has recently been developed which, up to a certain firing distance, has substantially the same ballistic properties as the live ammunition in question, but which has a significantly reduced maximum firing range when compared to normal live ammunition.

The advantage of using this new type of training ammunition is that such ammunition allows realistic military exercises on considerably smaller firing ranges than before.

An exemplary embodiment of such a training projectile is shown in German patent 1,678,197. This type 30 practice projectile is provided with a plurality of channels on its nose, which channels are configured to form an air stream in the channels and provide the projectile with a pulse opposite to its direction of rotation. In a modified version 8200213 i. . In a liner form, those channels may have been replaced by a number of blades, but again in this case it is the axial airflow used to provide the projectile with a pulse in a direction opposite to the direction of rotation of the projectile.

By providing the projectile with such means for deflecting the axial airflow, it is then possible to reduce the rotational speed of the projectile to such an extent that finally a critical value for the rotational speed is reached whereby the projectile is no longer stable in its trajectory but goes tilt 10 or tilt. When this takes place, the air resistance increases significantly with the result that the firing range is reduced.

A drawback of this type of projectile is that the deflection channels as well as the blades make the projectile relatively complicated and expensive. Furthermore, it is difficult to change the projectile for different shooting distances. By arranging such structures in the front part of the projectile, there is also a risk that the ballistic properties of the projectile may even be changed to the actual firing distance.

Accordingly, the primary object of the present invention is to provide a practice projectile that is easier to manufacture and can be easily modified for different firing distances. According to the invention, the cylindrical intermediate part of the projectile is provided with a number of aerodynamic surfaces which are oriented radially and which are parallel to the axis of symmetry of the projectile. The aerodynamic surfaces can be in the form of fins, which is suitable for a sub-caliber projectile, or formed by grooves or notches directly in the cylindrical surface, for example in the case of a full-caliber projectile. Both types have in common that the air resistance increases in the direction of rotation, which means that the rotational speed of the projectile after launching is reduced. For a specific rotation speed, the projectile becomes unstable and the projectile tilts. By setting the location, and / or number of surfaces, it is possible to let this critical speed occur at a specific distance, preferably 8200213-3 just behind the target distance for the practice shooting.

The invention will now be further elucidated with reference to the drawing.

Fig. 1 shows three different embodiments in which the aerodynamic surfaces are in the form of fins on the cylindrical intermediate part.

Fig. 2 shows a modified embodiment in which the aerodynamic surfaces are formed by grooves in the cylindrical surface.

10 The projectile shown is an example of a suitable projectile design and is basically the same for the different embodiments and contains a conical nose 1, a cylindrical intermediate part ("middle") 2 and a tailpiece 3. In this case the projectile is intended for to be launched by means of a separate drive belt (not shown) and it is therefore provided with a grooved tailpiece for the drive. For a full-caliber projectile, the tailpiece may have a different embodiment.

On the cylindrical intermediate part 2, four fins 4 are distributed symmetrically about the circumference of the body of the projectile 20 but in three different axial positions: at the front (fig. Ia) in the middle (fig. 1b) and at the back (fig. 1c) of the cylindrical part 2. The fins are directed axially, parallel to the axis of symmetry 5 of the projectile, and radially extend from the surface of the cylindrical part 2. In the axial direction, the fins extend about 1/3 of the length of the cylindrical part 2 and in its radial direction about 1/5 of the radius of the cylindrical part 2. For aerodynamic reasons, the front end surface 6 of the fins is cut out such that it forms an angle of about 45 ° with the axis of symmetry 5 of the projectile 30 and further, the edges of this end surface are machined at about 45 ° so that the fin has a sharp leading edge.

The rotational speed provided to the projectile upon exiting the barrel of the firearm is reduced by the braking effect of the side surfaces of the fins due to air resistance. When the rotation has decreased so much that the 8200213 - 4 - ». When the rotational speed has reached a specific critical value, the projectile is no longer stable, but it tilts or slopes, which means a significant and sudden increase in air resistance for the projectile so that its forward movement in its trajectory is also slowed down. This in turn means a significant reduction in the range when compared to normal live ammunition. By changing the dimensions of the fins, i.e. their radial and axial dimensions, as well. their axial positions allow the said instability to take place just behind the present target distance.

Compared to the known types of projectiles with channels or surfaces for axially deflecting an air stream, this new type of projectiles means a simpler construction.

The basic shape of the projectile's body is maintained.

Each fin can be mounted on the cylindrical intermediate part 2, but as an alternative embodiment, the fins can also be mounted on a replaceable ring screwed onto the cylindrical part 2. The latter alternative embodiment is preferred since in this case a number of replaceable rings with 20 different fin configurations adapted to different fire distances can be used. Such a ring 7 is shown in Fig. 1a and in this case the ring is arranged in a corresponding recess on the cylindrical surface of the intermediate part 2.

Fig. 2 shows an exemplary embodiment of an alternative embodiment. wherein the aerodynamic surfaces for slowing the rotational speed of the projectile are formed by grooves 8 on the cylindrical intermediate part 2. In accordance with the corresponding fins in Fig. 1, the grooves 8 are symmetrically distributed about the circumference of the body of the projectile 30 and the location, depth and axial size can be easily adjusted to the desired braking effect. If the grooves 8 do not extend over the entire axial length of the cylindrical intermediate part, for aerodynamic reasons the rear end 9 of the groove is preferably cut at an angle of 45 ° with respect to the axis of symmetry of the projectile.

8200213 - 5 - * *

The embodiment shown in FIG. 2 can be used for projectiles of both lower caliber and full caliber, but the embodiment of FIG. 1 with fins can only be used for bottom caliber projectiles. Projectiles of 5 caliber are equipped with separate drive belts and the resp. fins and grooves of the intermediate section are used as a support for the drive belt.

The invention is not limited to the above-mentioned exemplary embodiments, but can be modified within the scope of the following claims. By way of example, four symmetrically distributed fins are shown. Of course, a different number of fins can be used if appropriate. Furthermore, the respective fins and grooves can have an axial dimension corresponding to the length of the symmetrical intermediate part 2.

8200213

Claims (6)

Rotational stabilized training projectile with a conical nose, a cylindrical intermediate part and a tailpiece and provided with a braking member for reducing the rotational speed of the projectile after launch, characterized in that the braking member has a number of aerodynamic surfaces (4 , 8) disposed on the cylindrical intermediate part (2), oriented radially and parallel to the axis of symmetry (5) of the projectile. Projectile according to claim 1, characterized in that said aerodynamic surfaces are formed by fins 10 (4) which are arranged on the cylindrical surface of said intermediate part (2). Projectile according to claim 1, characterized in that the aerodynamic surfaces are formed by grooves in the cylindrical surface of said intermediate part (2). Projectile according to Claim 2 or 3, characterized in that the said fins (4) and grooves (8), respectively. symmetrically distributed about the circumference of said intermediate part (2). Projectile according to claim 2, characterized in that the fins (4) are arranged on a replaceable ring (7), which ring is arranged on said cylindrical intermediate part (2). 6. Projectile substantially as indicated in the description and / or shown in the drawing. 8200213