DE9010428U1 - Practice bullet - Google Patents

Description

The invention relates to a training projectile, in particular for anti-tank weapons, with a head consisting of a conical tip, an adjoining hollow-cylindrical thin-walled sleeve which encloses a filling core, and a connecting piece.

Such a training projectile is known from DE-OS 33 18 201. The training projectiles should, on the one hand, correspond as closely as possible to live ammunition in terms of their ballistic properties and, on the other hand, cause as little damage as possible to the targets used for training purposes.

In the known training bullet, the case with the conical tip forms a one-piece part that is screwed onto the connector after the filling core has been inserted. A disadvantage of this training bullet is that the case with the conical tip

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' ,Accounts/ Accounts

3*1. ODperiheimjr & Cie. Cologne (EJLZ J Vi 30200) KIo Mr 10760 ;. t^OtscheBank AG. Cologne (BLZ 370 7OO60)Klo No. 1165018 PoslgifoKoln (BLZ 3701005O)KIo No. 654-500

The mechanical tip is still too strong on impact and therefore the destruction of the kinetic energy of the bullet by bursting the casing and pulverizing the filling core is not possible quickly enough. This means that the force impulse concentrated on the point of impact cannot be dissipated quickly enough by distribution and the target object is damaged too much. A further disadvantage of the well-known, surviving bullet is that the casing with tip has to be manufactured at relatively high cost.

The invention is based on the object of creating a training projectile of the type mentioned at the beginning, which enables a faster and better distribution of the projectile's kinetic energy in the event of an impact and which can be produced more cost-effectively.

According to the invention, the features of the main claim serve to solve this problem.

The tip of the practice bullet is pressed into the case upon impact, whereby the expanding body forces the case to burst open, as the expanding body penetrates the filling core on inclined surfaces. The filling body is pressed radially symmetrically outwards, whereby the bursting tendency of the case wall is increased. In this way, it is achieved that immediately upon impact of the

3Q shot, the bursting of the casing is initiated and the kinetic energy of the mass of the filling core is distributed radially symmetrically over a large area due to the effect of the expansion body, whereby the bursting

bursting of the cartridge case is achieved definitively and in the shortest possible time. The kinetic projectile energy is distributed over a wide area, resulting in extremely low damage to the target object. The beveled surfaces convert the axial impact force directly into radial forces.

In one embodiment, it is provided that the expansion body consists of a ball, that the inclined surfaces are arranged in the filling core and that the ball rests on the inclined surfaces. The advantage of this embodiment is that it is easier to dismantle when using a relatively soft steel ball and a hardened tip.

In one embodiment, the sleeve including the connecting piece is manufactured in one piece, whereby the tip can also be manufactured as a turned part.

The tip can be made of solid material. This allows the weight distribution of the original ammunition to be better reproduced.

A further development provides for recesses to be arranged in the projection in a symmetrical manner to the longitudinal axis of the head. These recesses enable optimal adaptation to the weight distribution of the training projectile, which also makes it possible to adapt more flexibly to weaker propellant charges, if necessary for training purposes.

The filling core can be provided as a pressed body with round or conical recesses into which the expansion body can engage. It is preferably provided that the conical recesses of the filling core have an inclination corresponding to the expansion body, whereby the expansion body rests on the filling core. A preferred inclination of the conical surfaces is below 45°. The total impact energy of the practice projectile is initially transferred to the

1U tip and thus via the conical surfaces of the projection directly onto the filling core, whereby the impact energy is optimally converted into a fragmentation energy for the training projectile.

Preferably, the tip engages the free end of the case with the aid of a snap closure. With the aid of such a snap closure, the practice bullet can no longer be opened without causing damage, which prevents the practice bullets from being misused, for example by filling them with black powder or by other manipulations.

The tip can also be made as a plastic injection-molded part. Such a tip can be manufactured more cost-effectively.

The sleeve can have internal grooves on its inner surfaces that are parallel to the longitudinal axis of the head. These internal grooves serve as predetermined breaking points and make it easier to burst the sleeve body.

In the base formed by the connecting piece, a funnel-shaped recess can be arranged radially symmetrically to the longitudinal axis of the head, which weakens the base of the case and thus facilitates disassembly of the case body. This creates a predetermined breaking line for the base of the case, starting from the funnel-shaped recess to the free space at the end of the gun on the connecting piece.

In the following, embodiments of the invention are explained in more detail with reference to the drawings.

Show it

Fig. 1 a training projectile according to a first embodiment

Fig. 2 a training projectile according to a second embodiment ,

Fig. 3 is a section along the line III.3 in Fig. 2, and

Fig. 4 shows a third embodiment.

Fig. 1 is a longitudinal section through a head of a training projectile consisting of a sleeve 1, a connecting piece 2 and a tip 3, in which the sleeve 1 is made in one piece with the connecting piece 2. This connecting piece has an external thread 6 which is used to connect the head to a propellant charge, which can also have a tail unit, e.g. with swiveling guide vanes to stabilize the flight path.

■· 6 *~

At the free end of the sleeve 1, at a distance from its front surface, an annular groove 7 is provided, the flank 8 of which facing away from the free end is conical in such a way that the annular groove 7 opens radially inwards. An annular web 9 of the tip 3 engages in this annular groove 7, the annular web and the annular groove together forming a snap closure. Instead of the annular web 9, nose-shaped projections evenly distributed radially on the circumference of the tip 3 can also be provided. The outer diameter of the annular web 9 or the nose-shaped projections is slightly larger than the inner diameter of the sleeve 1. Instead of the snap closure between the sleeve 1 and the tip 3, a knurled or flanged closure can also be provided.

The free end of the case 1 is bevelled inwards at an angle of between 30° and 60', preferably 45°, in order to facilitate the penetration of the point 3 into the space surrounded by the case 1 when it impacts. Since the outer diameter of the edge 20 is larger than the inner diameter of the case 1, the case expands considerably when the practice projectile head impacts and the point 3 penetrates the case 1, so that it tears open in one or more places.

The tip 3 has a conical surface 10, the front part of the tip 3 being flattened. The tip 3 also has a projection 5 that projects into the space enclosed by the sleeve 1 and has a conical surface 11 that extends outwards to the ring web 9 or the nose.

shaped projections, so that this conical surface 11 rests on the correspondingly conical flank 8 of the annular groove 7. The conical surface 11, in conjunction with the bevel at the free end of the sleeve, facilitates the penetration of the plug-shaped tip 3 into the sleeve 1, which initially tears in the process.

The tip 3 can have a bore radially symmetrical to the longitudinal axis of the head, through which the weight distribution within the training projectile can be balanced with the help of the bore diameter and the bore depth.

Alternatively, another inclination of the conical surface 11 is shown in dashed lines in Fig. 1, with a preferred inclination being less than 45'.

The cavity enclosed by the sleeve 1 contains a filling core, e.g. made of iron powder and/or a ceramic powder, to which a binding agent, e.g. zinc stearate, can be added. In order to achieve a higher weight, the powder is preferably compacted or sintered. If the filling core is a pressed body, this can also have a recess 13 arranged radially symmetrically to the longitudinal axis of the head, e.g. a bore, which also serves, with the help of its size and length, to balance the weight distribution of the practice projectile. The recess 13 can also be funnel-shaped, as shown in dashed lines in Fig. 1.

The filling core 4, designed as a pressed body, has at its end facing the tip 3 a funnel-shaped surface 17 adapted to the conical surface 11 of the projection 5, such that the conical edge surface II of the projection 5 'lies at least partially on the funnel-shaped surface 17 &&agr;£- .

The filling core 4 can optionally be glued to the inner dumbbell surface 14 and the base 16, especially if a cavity is to remain between the filling core 4 and the projection 5 of the tip 3 The filling core 4 is glued to its base end

chamfered in the edge area.
15

The filling core 4 should have a density of at least 6.5 g/cm as a pressed body.

Longitudinal grooves 15 can be arranged in the inner dumbbell surface 14 of the sleeve 1, parallel to the longitudinal axis of the practice projectile, preferably evenly distributed around the circumference, which form predetermined breaking points for the bursting of the sleeve 1 (Fig. 3). The longitudinal grooves 15 extend from the conical flank 8 of the annular groove 7 to the base 16 formed by the connecting piece 2.

The longitudinal grooves 15 provided on the inner surface 14 are tapered in cross-section, preferably at an angle of 30*.

Fig. 2 shows an example of the training projectile, in which the truncated cone-shaped projection 5

is stepped, whereby loose powder can be located between the projection 5 and the filling core 4 produced as a pressed body in the recess 13 for precise weight calibration. The projection 5 can, as shown in Fig. 2 in dash-dotted lines, extend deep into the core 4 and be tapered. In these designs,

lation examples according to Fig. 2, the funnel-shaped

Surface 17 is reduced to a small frustoconical surface 10, so that when the practice projectile impacts, the tip 3 acts with extremely high surface pressure against the triangular surface 17 and thereby initiates the pulverization of the filling core 4 and the complete bursting of the case 1. Instead of a solid body ^, the filling core 4 can also be made entirely of loose powder, which is compacted when the tip 3 is inserted, so that no hollow spaces remain in the case 1 which could impair flight stability.

Unlike in the embodiment of Fig. 1, the outer diameter of the edge 20 of the tip 3 resting on the front face of the sleeve 1 can also correspond to the outer diameter of the sleeve 1 in order to create a secure stop for the assembly of the tip 3. The material thickness of the edge 20 resting on the front face of the sleeve 1 should be selected to be relatively thin in order to encourage the edge 20 to break away when the practice projectile impacts, supported by the notch effect due to the beveled front face of the sleeve 1. The tip 3 is recessed in the shape of an annular groove between the edge 20 and the ring web 9.

The base 16 of the sleeve 1 formed by the connecting piece 2 has a funnel-shaped recess 18 in its center, which is aligned rotationally symmetrically to the longitudinal axis of the head. This recess makes it easier to burst apart, especially the wall elements of the sleeve 1 divided by grooves 15. Furthermore, starting from the deepest point of the funnel-shaped recess, predetermined breaking lines are created to the undercut 19 at the thread run-out of the thread 6, which break open due to the weakening of the base cross-section and due to the torque generated by an impact. When the impact force acts on the front surface of the sleeve 1 and induces a longitudinal force there, a torque is created that acts on the base 16.

The sleeve 1, which is one piece with the connecting piece 2, is preferably made of case-hardened SMnPb28K according to DIN 1651 or of St4 according to DIN 1624. The tip 3 can be made of the same material as a turned part or as a plastic injection-molded part.

Fig. 4 shows a third embodiment in which the sleeve (1) is in one piece with the tip (3) and the sleeve (1) is screwed onto the connector (2). The filling core (4) is provided with a conical recess (13) which concentrically accommodates a relatively small steel ball (3') as an expansion body (3'). The filling height of the filling core (4) as a pressed part

3Q is such that a free space remains around the ball (3· ¹ ) in the head of the practice projectile. The tip, which is one piece with the casing (1), is the preferred

hardened, which in conjunction with the relatively soft steel ball (3') results in better dismantling of the training projectile.

Claims (15)

Expectations 1. Training projectile, especially for anti-tank weapons, with a head consisting of a conical tip, an adjoining hollow cylindrical thin-walled casing which encloses a filling core and a connecting piece, characterized , that between the tip (3) and the filling core (4) there is arranged an expansion body (3 ¹ ) which, via conical inclined surfaces (17), deflects the axial impact force on the tip (3) into outward-directed radial forces via the filling core (4) onto the inner walls of the sleeve. 2. Training projectile according to claim 1, characterized in that the expansion body (3 ¹ ) consists of a "jug (3 ¹¹ ) exists, that the inclined surfaces (17) are arranged in the filling core (4) and that the ball (3··) on the inclined surfaces (17) rests. 3. Training projectile according to claim 1 or 2, characterized in that the tip (3) and the sleeve (1) are one piece. 4. Training projectile according to claim 1 or 2, characterized in that the sleeve (1) is made in one piece with the connecting piece (2), that the expansion body (3 ^C ) is placed on the free end of the cylindrical sleeve part (1), that the expansion body (3 ¹ ) has a projection (5) which projects into the filling core (4) and is at least partially spherical or conical, and that the expansion body (3·) simultaneously forms the tip (3). 5. Training projectile according to claim 4, characterized in that the tip (3) consists of solid material. 6. Training projectile according to claim 5, characterized in that at least one recess (12) is arranged in the projection (5) rotationally symmetrical to the longitudinal axis of the head. 7. Training projectile according to one of claims 1 to 6, characterized in that the filling core (4) is provided as a pressed body with a recess (13) into which the expansion body (3 ¹ ) at least partially engages. 8. Training projectile according to claim 7, characterized in that the recess (13) of the filling core (4) and the expansion body (3 ¹ ) are adapted to one another in such a way that the expansion body (3·) rests on the filling core (4). 9. Training projectile according to one of claims 4 to 8, characterized in that the tip (3) is inserted into the sleeve (1) by means of a snap closure (7, 9). 10. Training projectile according to claim 9, characterized in that the snap closure is formed from an annular groove (7) provided in the sleeve (1) and a projection (9) of the tip (3) adapted to the groove, whereby the flank (8) of the annular groove (7) facing away from the free end of the sleeve (1) extends in such a way that it widens the annular groove (7) radially inwards. 11. A projectile according to one of claims 4 to 10, characterized in that the tip (3) is a plastic injection-molded part. 12. Training projectile according to one of claims 1 to 11, characterized in that the sleeve (1) has longitudinal grooves (15) parallel to the longitudinal axis of the head. 13. Training projectile according to claim 12, characterized in that the flanks of each longitudinal groove (15) in cross section taper towards one another at an angle of preferably approximately 30°. 14. Training projectile according to one of claims 1 to 13, characterized in that the filling core (4) consists of a compacted or sintered metal and/or ceramic powder. · - » ■
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· tt 15. Training projectile according to one of claims 1 to 14, characterized in that a funnel-shaped depression (18) arranged radially symmetrically to the longitudinal axis of the head is arranged in the base (16) formed by the connecting piece.