FR2498749A1 - INSTRUCTION PROJECTILE WITH ADJUSTABLE RANGE OF SHOOTING - Google Patents

Abstract

PROJECTILE OF INSTRUCTION STABILIZED BY ITS ROTATION. IT INCLUDES A CONICAL NOSE 1, A CYLINDRICAL INTERMEDIATE PART 2 AND A TAIL 3, AS WELL AS AERODYNAMIC SURFACES SHAPED BY FINS 4 OR THROATS OF THIS INTERMEDIATE PART. THESE FINS OR GROOVES ARE RADIALLY ORIENTED AND ARE PARALLEL TO THE SYMMETRY 5 AXIS OF THE PROJECTILE. THEY DECREASE ITS ROTATION SPEED AND ITS SPEED ON ITS TRACK, AND MAKE IT UNSTABLE WHEN THIS SPEED REACHES A CRITICAL VALUE. PROPER DETERMINATION OF DIMENSIONS AND ARRANGEMENT OF THE FINS OR THROATS WILL RESULT IN INSTABILITY JUST BEYOND THE TARGET DISTANCE. THE PROJECTILE PRESERVES ITS BALLISTIC PROPERTIES UP TO THIS TARGET, BUT ITS MAXIMUM RANGE IS LOWER THAN THAT OF A NORMAL CHARGED PROJECTILE. APPLICATION TO SHOOTING EXERCISES, IN PARTICULAR ON POLYGONES OF RELATIVELY RESTRICTED DIMENSIONS.

Description

The present invention relates to an instructional projectile which is

stabilized by his own speed of

  rotation, which includes a conical nose, an intermediate part

  cylindrical diane and a tail and which has braking elements for reducing this rotational speed

once it has been launched.

  For military training, ammunition

  normally replaced by ammunition

  special training, with a view to achieving savings.

  These training ammunition are often simpler than normal loaded ammunition, in order to reduce shooting expenses. In order to allow soldiers to be trained in almost normal shooting conditions, it is important that

  ballistic properties of training ammunition cor-

  correspond substantially to those of loaded ammunition

  they replace. As a result, the maximum range of

  instructions corresponds to that of these char-

  elderly. But it also means that military training sessions must take place on the very few very large polygons and that relatively large areas must be closed.

to allow shooting.

  As a result, a new kind of training projectile has recently been proposed which, to a predetermined distance, has virtually the same

  ballistic properties that the loaded ammunition corresponds

  but have a maximum range significantly lower than these normal loaded ammunition. The advantage of

  the use of training ammunition of this new type is that it

  puts realistic military training sessions on

  polygons significantly smaller than before.

  An example of an instructional projectile of this kind

  is given in the patent of the Federal Republic of Germany

  No. 1,678,197. This type of training projectile

  carries on its nose a number of grooves which are

  so that a flow of air is created

  the projectile an impulse opposite to its direction of rotation.

  In an alternative embodiment, these grooves may be replaced by fins 7, but in this case too, it is the axial air flow that serves to give the projectile a

  impulse in the opposite direction to its direction of rotation.

  By providing the projectile with such elements, intended to deflect the axial air flow, it is thus possible to reduce the rotation speed of this projectile, sufficiently to reach a critical value at which this projectile has more stable trajectory, but rocks or tumbles. When this happens, the air resistance increases considerably, so that the range

shooting is reduced.

  A disadvantage of projectiles of this type consists in the fact that the deflector grooves and the fins make it relatively complicated and expensive. Moreover, it is difficult to modify the projectile to adapt it to different shooting distances. Having these elements on the front of the projectile may also change its ballistic properties before

even the actual shooting distance.

  Therefore, the present invention essentially relates to a training projectile simpler to manufacture and can be easily modified and adapted to different shooting distances. According to the present invention, the cylindrical intermediate portion of the projectile comprises a number of oriented aerodynamic surfaces.

  radially and parallel to the axis of symmetry of this projec-

  tile. Aerodynamic surfaces can be realized under

  the shape of fins, which is suitable for a sub-projectile

  calibrated, or formed by formed grooves or grooves

  directly on the cylindrical surface, in the case for example

  of a full caliber projectile. What is common to both

  types is that the resistance of the air in the direction of rotation

  This is increased, ie the rotational speed of the projectile is reduced after launch. At a determined rotational speed, the projectile becomes unstable and

  rocker. It is possible, by changing the position, the di-

  and / or the number of surfaces, to make sure that critical speed is reached at a determined distance, preferably just beyond the distance of the target for

firing training.

  Non-limiting examples of the invention will be described in more detail with reference to the accompanying drawings in which: Figures 1a, 1b, 1c show three embodiments in which the aerodynamic surfaces are constituted by fins disposed on the cylindrical intermediate portion; and FIG. 2 represents a variant embodiment in which the aerodynamic surfaces are formed by

  grooves of the cylindrical surface.

  The projectile body shown in the figures

  is an example of an appropriate conformation, which is

  mentally identical in the various embodiments and which comprises a conical nose 1, a cylindrical intermediate portion ("belt") 2 and a tail 3. In this case, the projectile is intended to be launched by means of a forcing belt distinct (not shown) and its tail includes

  so gorges of training. For a full projectile

  free, the tail can have another conformation.

  Four fins 4 are symmetrically distributed on the periphery of the cylindrical intermediate portion 2 or body of the projectile, in three different axial positions: at the front (Figure la), in the middle (Figure lb) and at the rear (Figure lc) of this cylindrical portion 2. The fins are biased axially, parallel to the axis of symmetry of the projectile, and protrude radially from the surface of the cylindrical portion 2. In the axial direction, the fins are about a third of the length of the cylindrical portion 2, and they have in the radial direction about one fifth of the radius of this cylindrical portion 2. For aerodynamic reasons, the surface 6 of the front end of the

  fins has been cut to approximate

  45 with the axis of symmetry 5 of the projectile and, in addition, the edges of this end surface have been machined to about 450, so that the fins have the front

a sharp edge.

  The speed of rotation which has been given to

  at the exit of the barrel of the weapon is reduced by the

  braking effect of the lateral surfaces of the fins, in

  sound of air resistance. When the rotational speed

  has been reduced enough to reach a certain critical value, the projectile is no longer stable, but tossing or tumbling, causing a significant increase

  and sudden resistance from the air, so that his displacement

  cement forward on its trajectory is also braked.

  It also means that the maximum range of fire is appreciably reduced compared to that of a normal loaded projectile. It is possible, by modifying the dimensions of the fins, that is to say their radial and axial extent, as well as their axial position, to make this instability

  occurs just beyond the distance of the target.

  Compared to projectiles of the earlier type with groove

  or surfaces intended to axially deflect a cou-

  air, this new type of projectile is simpler to manufacture. The basic shape of the body of the projectile is preserved. Each of the fins may be disposed on the cylindrical intermediate portion 2, but, alternatively, they may also be arranged on a removable ring, screwed onto this cylindrical portion 2 and replaceable. This

  last variant is preferred because it is then possible to

  use of a number of removable rings carrying fins of different configurations corresponding to different shooting distances. A ring 7 of this kind has been shown in FIG. 1a and, in this case, it is

  disposed in a corresponding groove of the cylindrical surface

  drique of the intermediate part 2.

  Figure 2 represents another example

  embodiment in which the aerodynamic surfaces

  to reduce the rotational speed of the projectile

  are formed by grooves 8 of the intermediate part cy-

  2. As well as the corresponding fins of the

  FIGS. 1a to 1c, the grooves 8 are distributed symmetrically around the periphery of the body of the projectile, and it is possible to adapt their position, their depth and their axial length to the desired braking action. If throats 8 have

  not the entire axial length of the intermediate part cy-

  lindrique, their posterior end.9 is advantageously

  machined to form an angle of 450 with the axis of symmetry

  sort of projectile, for aerodynamic reasons.

  The embodiment shown in FIG. 2 can be used for under-sized projectiles as well as for full-caliber projectiles, but the fin embodiment of FIGS.

  used only for sub-calibrated projectiles. Projections

  sub-calibrated tiles are equipped with separate forcing belts and fins and grooves, respectively,

  of the intermediate part can be used to

these belts.

  The invention is not limited to the forms of

  These examples can be modified in the context of the invention. So,

  it has been shown by way of example four fins distributed

  symmetrically. It is of course possible to use another number of fins, if it is suitable. In addition, the fins and grooves, respectively, may have

  an axial length corresponding to that of the

cylindrical intermediate.

  It goes without saying that it is possible to bring

  other modifications to the training projectiles

  described and described without departing from the scope of the invention.

Claims (5)

  1. Training projectile stabilized by its   rotation, comprising a conical nose, an intermediate part   re cylindrical and tail, as well as braking elements   swimming intended to decrease its speed of rotation once   that it was launched, projectile characterized in that the ele-   braking elements are aerodynamic surfaces (4, 8)   disposed on the cylindrical intermediate portion (2),   radially and parallel to the axis of symmetry (5) of this projectile.   2. Projectile according to claim 1, characterized   in that the aerodynamic surfaces are formed by   fins (4) which are arranged on the cylindrical surface   drique of the intermediate part (2).   3. Projectile according to claim 1, characterized   in that the aerodynamic surfaces are formed by grooves (8) of the cylindrical surface of the part intermediate (2).   4. Projectile according to one of claims 2   and 3, characterized in that the fins (4) and the grooves (8), respectively, are symmetrically distributed on the   periphery of the intermediate part (2).   5. Projectile according to claim 2, characterized   in that the fins (4) are arranged on a removable ring (7), which is mounted on the intermediate portion cylindrical (2).