CH658717A5 - FLOOR, ESPECIALLY FOR EXERCISE PURPOSES. - Google Patents

Description

The present invention relates to a projectile, in particular for training purposes, with a cylindrical middle part and an associated cylindrical nose section in the form of a rod, which has a diameter that is much smaller than the diameter of both the middle part and a tail section.

In order to reduce the costs of shooting, war ammunition is usually replaced by special practice ammunition during military exercises. In such cases, it is important that the ballistic properties of the practice ammunition are largely the same as those of the war ammunition that they replace. Various versions of such practice ammunition have become known.

In order to meet the requirements with regard to corresponding ballistic properties up to a specified distance, it was previously assumed that, for example, the maximum firing range of a respective practice bullet must also correspond to the maximum firing range of the war ammunition projectile, which is thereby replaced. However, this means that in order to be able to carry out military exercises, relatively large areas must be closed off.

An object of the present invention is to provide a projectile, in particular for training purposes, which allows considerably smaller training areas in comparison to formerly. The projectile according to the invention is characterized by the features of claim 1. This invention is based on the finding that a rod, known in the art as a spike, has favorable ballistic properties.

The noticeably smaller firing range can e.g. half of the maximum range of war ammunition.

According to a preferred embodiment of the invention, the length of the rod is 1.65 to 1.85 times the same, and in particular 1.7 to the diameter of the central part.

Advantages of an embodiment of the subject matter of the invention are described in detail below, in particular also the tail section of the projectile.

When using a rod-shaped nose, a so-called congestion area is obtained around the rod at supersonic speeds, which means that the braking effect of the radially standing end face is eliminated. At subsonic speeds, however, the air flow follows the surface of the rod and the radial face, which means that a considerable braking force is exerted on the projectile. This means that the bullet has a largely interference-free ballistic bullet trajectory at supersonic speeds, but as soon as the bullet's speed has been reduced to subsonic speeds, a considerable braking force is exerted on the bullet. Because of this braking force, a considerably reduced maximum firing range is obtained. The rod causes the bullet to be more stable at supersonic speeds as well as subsonic speeds and even when penetrating the speed of sound. By using the proposed rod-shaped nose, the distance between the so-called Tp and Tc points (see below) can be reduced noticeably up to a value of up to one caliber. The special design of the tail section also contributes to the stability of the projectile. The new training enables the bullet to be manufactured efficiently and economically using cold presses. Cold pressing, i.e. Cold forming means that the mechanical strength of the projectile is increased, so that, for example, heat treatment of the projectile body is not necessary. This also means that the danger that the caudal fins and the guide surfaces distort during the heat treatment is eliminated. Cold pressing also means that the projectile is pressed into the largely final product in one work step. After the cold pressing, only a small twisting off and the attachment of the guide ring and the drive ring, if available, will be necessary. It should be emphasized that the shape of the projectile and its manufacturing process result in savings in terms of material, energy and costs.

A preferred embodiment of the invention is explained in more detail below with reference to the accompanying drawings. It shows:

1 is a perspective view from behind of a practice floor,

2 shows the practice floor of FIG. 1 in a diagrammatic view from the front end thereof,

3 is a side view of the projectile shown in FIGS. 1 and 2,

4a shows a schematic side view of the air flow conditions at supersonic speeds of the training floor according to FIGS. 1 to 3,

5a shows a ballistic diagram for a defined shooting range for a practice bullet according to the present invention and for a conventional one corresponding to it

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Projectile of war ammunition,

5b shows a ballistic diagram for the maximum firing ranges of a training projectile according to the invention and also for a conventional projectile of war ammunition corresponding thereto,

6a shows a side view of a cylindrical workpiece which is used as a blank in the production of the new projectile by means of cold pressing, and

Fig. 6b is a schematic side view of the point in time of the manufacturing process at which the training floor has received its final shape in a symbolic pressing tool.

1 to 3 show a practice bullet which has a largely cylindrical central part 1, to which a nose in the form of a rod 2 and a tail section 3 are connected. Such a rod-shaped nose 2, also called a spike, is known. The rod-shaped nose is basically cylindrical and has a diameter d that is much smaller than the outer diameter D of the cylindrical part, and it can be mentioned, for example, that the diameter d of the rod is approximately Vi of the diameter D of the central part. The tail section has a number of wings or guide surfaces 3a, for example six guide surfaces.

The rod 2 has a length L, which in this case is approximately 1.7 times the diameter D of the central part. However, depending on the caliber (projectile diameter), type of ammunition etc., this length L is between 1.6 and 2.0 times the diameter D and preferably between 1.65 and 1.85 times the same.

The length Li of the tail section 3 is greater than the length Li of the rod 2 or the length L3 of the middle part 1. The guide surfaces extend in the longitudinal direction with the full caliber (i.e. the geometric envelope cylinder determined by this) along the larger part of the tail section. In the connection area with the central part, however, the guide surfaces are slightly beveled up to a sub-caliber dimension, so that the outer edge surfaces 3a 'of the guide surfaces converge towards the central part. The rear end section of the intermediate part is designed as a truncated cone la with a cone angle α, which angle has a value between 10 ° and 20 °, preferably 15 °. The conical surface converges towards the rear in such a way that it is the same as or corresponds to that of the front ends of the edge surfaces 3a 'of the guide surfaces. The length of the conical section is 1-3%, preferably 2% of the total length of the projectile. The purpose of this conical section is to guide the longitudinal air flow flowing along the outer surface of the central part into the space between the guide surfaces 3a in order to improve the stability of the projectile.

In this case, the length L3 of the central part is less than the length of both the rod and the tail section. The middle part has a front circumferential groove and a rear circumferential groove, such that a guide ring 4 can be used at the front and a drive ring 5 at the rear. The guide ring and also the drive ring are made of a plastic, for example acetal or another corresponding material.

In Fig. 3, the center of gravity is indicated by Tp and the pressure center by Tc, and the distance between Tp and Tc, which is important in relation to the stability properties of the projectile, is designated by A.

4a and 4b show the air flow conditions at supersonic speed and at subsonic speed of the projectile. 4a (supersonic speed), the shock wave is indicated by 6, and a stagnation area of the air in the form of a rotationally symmetrical zone around the rod of the projectile is indicated by 7. This zone is delimited by the outer circumferential surface of the rod, a radial end face 1b on the middle part and a straight, conical, imaginary outer surface 8 which extends from the end face of the rod to the circumference of the radial end face 1b. An undisturbed air flow is obtained along the rectilinear outer side 8, which flows in the direction indicated by the arrows 9, in such a way that no braking action acting on the projectile is produced from the radial end side.

This means that at supersonic speeds, the projectile has a ballistic projectile trajectory, as is the case for a projectile with a pointed arch nose, a conical nose or a corresponding nose shape. The rod-shaped nose moves Tp and Tc backwards along the longitudinal axis of the projectile and increases the extent of the distance A, which ensures the desired high stability of the projectile. It should be noted that the bullet is stable not only at supersonic speeds, but also when passing through the speed of sound and at subsonic speeds.

4b shows the air flow conditions at subsonic speeds. The air flow 10 follows in this case the outer side surface of the rod and the radially standing end face 1b of the middle part. This means that the radially standing front side exerts a braking effect on the speed of the projectile, which considerably reduces the maximum range of fire, for example this is reduced by half in comparison with the range of a conventional, sharp projectile.

5a and 5b show the ballistic properties of the training projectile in comparison with a corresponding normal live projectile of war ammunition. For example, the comparison is made with a Bofors 9 cm model 77 war projectile, which has a weight of approximately 36.3 N. The practice floor also has a caliber of 9 cm and a weight of approximately 29.4 N. The Y-axis denotes the height of the bullet trajectory in meters and the X-axis the shooting range, also in meters. The maximum specified firing range for the ammunition in question is 800 m.

The bullet trajectory a is that of the sharp bullet and the bullet trajectory b is that of the practice bullet when these are fired by a gun with a muzzle velocity Vo = 670 m / s or Vo = 715 m / s. It can be seen that the ballistic properties of the two projectiles are largely the same up to a specified firing range, which means that realistic exercises can be carried out with the given artillery piece.

Diagram 5b shows the ballistic firing trajectories for a maximum firing range, the Y axis denoting the height and the X axis the firing range in meters. The bullet trajectory a 'of the war ammunition bullet is more than double (6000 m) than the maximum range of the training bullet. This is due to the relevant braking of the flight of the training floor at subsonic speeds. It should be noted that the bullet is stable at all speeds, for example between 0 and 3 times the speed of sound. This means that the individual levels of the practice ammunition can be easily tracked and found.

The training floor described is advantageously produced using a cold press process. A workpiece, the blank, is inserted into a cold pressing tool, the projectile then being produced in the tool in a single step, such that the rod-shaped nose and the wings are produced or formed in one and the same working step. The projectile is then turned on

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brought into the final shape using a lathe.

FIG. 6a shows a workpiece 11: a blank that serves as an initial piece, for example for a 9 cm practice bullet. This starting piece has a cylindrical body with a diameter of 92 mm and a length of 200 mm. The pressing tool halves are labeled 12.12 '. The pressing is carried out in only one step, and FIG. 6b shows the product formed in the tool, the partial plane being indicated by De and the molding space by F.

After the projectile body has been pressed and removed from the tool, it is rotated on a lathe to the final shapes and dimensions, for example in accordance with the embodiment shown in FIG. 3. The length of the final bullet in this case is approximately 465 mm.

The cold pressing and cold forming processes are known as such 5 and are therefore not described in more detail in this connection.

The invention is not limited to the described embodiment, but can be modified within the scope of the claims. For example, the invention is not limited to practice ammunition, but can also be used for war ammunition.

An important advantage of the projectile described is that it can be easily manufactured in large series.

4 sheets of drawings

Claims (6)

658 717 1. Projectile, in particular for training purposes, with a cylindrical middle part (1) and a cylindrical nose section connected thereto in the form of a rod (2), which has a diameter (2) that is much smaller than the diameter (D) of both the middle part ( 1) and a tail section (3), characterized in that the length (Li) of the rod (2) is 1.6 to 2.0 times the diameter (D) of the central part (1) and the tail section (3 ) Has wings (3a), which run with the full caliber over the greater part of the length (Li) of the tail section (3), such that the projectile has up to a defined firing range approximately the same ballistic properties as a projectile for war ammunition, however has a noticeably smaller firing range compared to war ammunition. 2. Projectile according to claim 1, characterized in that the length (Li) of the rod (2) is 1.65 to 1.85 times the diameter (D) of the central part (1). 2nd PATENT CLAIMS 3. Projectile according to claim 2, characterized in that the length (Li) of the rod (2) is approximately 1.7 times the diameter (D) of the central part. 4. Projectile according to one of the preceding claims, characterized in that the length (L2) of the tail section (3) is greater than the length (L3) of the central part (1) and is also greater than the length (Li) of the rod (2). 5. Projectile according to claim 4, characterized in that the central part (1) at the rear end has a conical section (la) in the form of a truncated cone, which conical section has an axial extent of 1-3%, preferably 2% of the total length ( Li + L2 + L3) of the projectile, and that the front end of the wings (32) is tapered to a sub-caliber dimension such that the wing edge surfaces (3a ') converge towards the front and determine an envelope whose diameter is equal to the diameter of the smallest Is part of the conical section (la). 6. Projectile according to one of the preceding claims, characterized in that the central part (1) has a guide ring (4) made of plastic and a drive ring (5) made of plastic.