NO150095B - OEVELSESPROSJEKTIL. - Google Patents

Description

The present invention relates to a rotationally stabilized practice projectile of the kind which, up to a certain firing distance, has mainly the same ballistic properties as the combat ammunition in question, but which has a maximum firing range which is mainly reduced in relation to the conventional combat ammunition, comprising a front conical part, a cylindrical middle part and a compared to the conical part and the middle part short, truncated tail part and provided with a number of aerodynamic surfaces essentially radially directed, as well as parallel to the symmetry of the projectile

axis.

It is previously known by practice shooting of

economic reasons to replace the usual combat ammunition with practice ammunition. This practice ammunition then usually has a simpler structure than the normal combat ammunition in order to reduce the costs of practice shooting. However, a requirement for the practice ammunition has been that it must at least have mainly the same ballistic properties as the combat ammunition that it will replace, so that the practice shooting will be as realistic as possible. This requirement has then meant that e.g. the maximum firing range for practice ammunition

tion had to correspond to the maximum firing range for the combat ammunition in question. This in turn has meant that practice shooting has been referred to a small number of large shooting ranges and that relatively large areas had to be canceled to allow practice shooting.

As a result of this, a type of practice projectile has recently been proposed which, up to a certain firing distance, mainly has the same ballistic properties as the corresponding combat ammunition, but which has a maximum firing range that is mainly reduced in relation to conventional combat ammunition. The advantage of such practice commu-

tion is that realistic shooting exercises can be carried out on a significantly smaller practice field than has previously been the case.

An example of a practice projectile of the above

species is described in German patent 1 678 197. This practice projectile comprises in its front part a number of channels which are designed in such a way that an air flow is formed in

the channels and gives the projectile an impulse in the opposite direction to the projectile's direction of rotation. In an alternative embodiment, these channels can be replaced by a number of vanes 7, but also in this case it is the axial air flow that is utilized to give the projectile an impulse which is opposite to the projectile's direction of rotation.

By designing the projectile in this way with organs that deflect the axial airflow, the projectile's rotation can be slowed down so much that it eventually reaches a critical value, where the projectile is no longer stable in its path, but tips or overturns. Thereby, air resistance increases very strongly and the result is that the firing range is limited.

A disadvantage of the described projectile is that both the deflection channels and the vanes make the projectile relatively complicated and thus expensive to produce. It is also difficult to adapt the projectile to different shooting distances. In the event of the intervention in the projectile's front part, there is also a risk that the projectile's ballistic properties will also change up to the firing distance.

From DE-OS 2 831 574, a rotationally stabilized practice projectile is also previously known, where the projectile body forms a Y-shaped cross-section, so that a number of braking fins are formed which slow down the projectile's rotation so that it becomes unstable and has a limited firing range. The Y-shaped cross-section extends substantially over the entire length of the projectile including its pointed front part and gives the projectile a shape which differs mainly from a conventional cylindrical projectile. The projectile becomes relatively complicated to manufacture and it is not clear how it can be adapted for different shooting distances.

The purpose of the present invention is therefore

to provide a practice projectile which is simpler from a manufacturing point of view and which can also be easily adapted to different shooting distances. That which thereby in it

essential can be considered to characterize the invention is that the aforementioned aerodynamic surfaces are formed immediately on the mantle surface of the projectile's cylindrical middle part and have an extent in the radial direction which is significantly smaller than the radius of the projectile's cylindrical middle part and a limited extent also in the axial direction, so that extends along only part of the cylindrical intermediate part. In this case, the aerodynamic surfaces can either be designed as fins which are suitable for an under-calibrated projectile, or formed by grooves or recesses which are placed directly in the cylindrical surface, e.g. by a full caliber projectile. Both types have in common that the air resistance increases in the projectile's direction of rotation and results in the projectile's rotational movement slowing down after firing. At a certain rotational speed, the projectile becomes unstable and "topples". By adjusting the positions, size and/or number of the surfaces, this critical number of revolutions can be made to occur at a desired distance, usually immediately after the target distance in practice shooting.

In the following, the invention will be described in more detail in connection with the drawings as shown in fig. 1 shows three different designs in the case that the aerodynamic surfaces are formed by fins on the cylindrical intermediate part and in fig. 2 shows an alternative embodiment where the aerodynamic surfaces are formed by cutting out grooves in the cylindrical surface.

The projectile body shown in the drawings is an example of a suitable projectile shape and in its basic form is identical in all cases and comprises a conical tip 1, a cylindrical middle part 2 and a tail part 3. The projectile is in this case designed for launch using a driving mirror (not shown) and is therefore provided with a tail section with grooves for entrainment. However, in the case of a full-calibre version, the tail section can have a different shape.

On the cylindrical intermediate piece 2, four fins 4 are arranged symmetrically around the circumference of the projectile, but axially in three different places: furthest forward (fig. a), in the middle (fig. b) and furthest behind (fig. c) on the cylindrical intermediate part. The fins are axially oriented, i.e. parallel to the projectile's symmetry axis 5 and extend essentially radially from the cylindrical intermediate part 2. In the axial direction, the fins occupy approximately one third of the length of the cylindrical intermediate part and in the radial direction approximately one fifth of the radius of the cylindrical intermediate part 2. For aerodynamic reasons, the front transverse surface 6 of the fins is

chamfered so that it forms 45° with the projectile's axis of symmetry 5 and further the edges are ground down approximately 45° so that the fins form a forward point.

As the projectile turns after leaving the gun's barrel, the side surfaces of the fins, due to air resistance, will slow down the projectile's turning motion. When this movement is slowed down so much that the rpm is below a certain critical value, the projectile is no longer stable, but tips or overturns, which means that the projectile's air resistance increases suddenly so that its forward movement is also slowed down. This again means that the maximum firing range is significantly reduced compared to ordinary combat ammunition. By choosing the size of the fins, i.e. their extent in the radial and axial direction and their position in the axial direction in a suitable way, the said lack of stability can be made to occur immediately after the target distance in question. Compared to previously proposed channels or surfaces for deflection of the air flow in the axial direction, the described projectile entails a significant simplification from a production point of view. No intervention in the basic shape of the projectile body is necessary. The fins can be placed separately on the cylindrical intermediate part 2 but can also alternatively be placed on an exchangeable ring which is threaded onto the cylindrical intermediate part 2. The latter has an advantage because then a number of exchangeable rings can be used with different shapes of the fins adapted for different shot distances. In fig. 1a, such a ring 7 is indicated, which in this case is embedded in a corresponding recess in the cylindrical surface of the intermediate part 2.

In fig. 2 shows an alternative embodiment, in which aerodynamic surfaces for slowing down the projectile's rotational movement are formed by means of grooves 8 in the projectile's cylindrical middle part 2. Like the fins, the grooves 8 are symmetrically arranged around the circumference of the projectile and the placement, depth and extent of the grooves in the axial direction can be easily adapted for the braking effect you want to achieve. If the grooves 8 do not occupy the entire cylindrical intermediate part in the axial direction, the groove ends appropriately with a chamfer 9 of 45° for aerodynamic reasons.

The embodiment according to fig. 2 can be used both for sub-calibre and full-calibre projectiles, while the variant according to fig. 1 with fins is used for under-calibre projectiles. In the case of such under-calibrated projectiles, the projectile is supplied with a driving mirror and in this case the fins or the grooves in the middle part are advantageously used as support for this driving mirror.

In the embodiments shown above as exemplary embodiments, e.g. indicated four symmetrically arranged fins respectively. traces. It will be clear that another number can also be chosen.

Claims (7)

1. Rotationally stabilized practice projectile of the kind which, up to a certain firing distance, has mainly the same ballistic properties as the combat ammunition in question, but which has a maximum firing range which is mainly reduced in relation to the conventional combat ammunition, comprising a front conical part, a cylindrical middle part and a compared with the conical part and the middle part short, truncated tail part and provided with a number of aerodynamic surfaces (4, 8) essentially radially directed, as well as parallel to the projectile's axis of symmetry (5), characterized in that the said aerodynamic surfaces (4, 8) are formed immediately on the mantle surface of the cylindrical middle part of the projectile and have an extent in the radial direction which is significantly smaller than the radius of the cylindrical middle part of the projectile (2) and a limited extent also in the axial direction, so that they extend along only part of the cylindrical middle part . 2. Projectile according to claim 1, characterized in that the aerodynamic surfaces (4, 8) have an extension in the axial direction of approximately 1/3 of the length of the cylindrical intermediate part. 3. Projectile according to claim 1, characterized in that the aerodynamic surfaces are formed by fins (4) placed directly on the cylindrical surface of the intermediate part (2). 4. Projectile according to claim 3, characterized in that the fins (4) in the radial direction have an extent of approximately 1/5 of the radius of the cylindrical intermediate part (2). 5. Projectile according to claim 1, characterized in that the aerodynamic surfaces are formed by grooves (8) taken up directly in the cylindrical surface of the intermediate part (2). 6. Projectile according to claim 3 or 5, characterized in that the fins (4) and the grooves (8) are symmetrically arranged around the periphery of the middle part. 7. Projectile according to claim 3, characterized in that the fins (4) are arranged on a replaceable ring (7) which in turn is placed on the cylindrical intermediate part (2).