DE3736167A1 - Arrow projectile having a conical discarding sabot, the conical discarding sabot separation being actuated by centrifugal force - Google Patents

Abstract

In the case of the arrow projectile having a conical discarding sabot, with the conical discarding sabot separation being actuated by centrifugal force, in order to prevent the rotation rate (spin) of the conical discarding sabot being transmitted to the arrow projectile as the projectile passes through the barrel, the connection from the conical discarding sabot to the arrow projectile is designed as a low-friction rotating bearing or as a screw and nut, in the case of which the tangent to the pitch angle is designed to be equal to or slightly greater than the coefficient of friction between the projectile shaft and the bore in the conical discarding sabot. As it passes through the barrel, the conical discarding sabot then completes a helical movement about the barrel shaft in the direction of the projectile nose (the projectile not completing any rotational movement, or completing only a slight rotational movement, about the longitudinal axis). When the projectile emerges from the firing barrel, the centrifugal force acting (at right angles to the firing direction) on the individual segments of the conical discarding sabot causes the discarding sabot to separate from the projectile. In order to assist the separation process, the front mouth of the thread on the projectile shaft can be designed as a conical extension of the projectile nose. When the front part of the conical discarding sabot runs onto the conical thread mouth, as a result of the helical movement, the individual segments of the conical discarding sabot are spread apart. The separation process is thus assisted.

Description

The "propelling cone arrow projectile with centrifugal propulsion separation; it is a sub-caliber arrow or rod projectile (caliber = diameter) that is drawn from a drawn tube (because trains are brought into the tube to initiate the twist on the projectile The sealing of the projectile ( 1 ) in the launch tube against the combustion gases of the propellant charge due to the smaller projectile diameter compared to the inside diameter of the projectile is brought about by a component which, depending on the form of execution: sabot, traction sheave, cage etc In the case of the projectile according to the invention, the designation "propellant cone" seemed to be the more appropriate. Such projectile concepts are known and in some cases were produced in large numbers. The development of the lower-caliber projectiles was based on the fact that an increase the breakthrough performance with increased target distance in the known pipe weapon systems is only possible when increasing the bullet speed and by increasing the bullet mass per unit area of the bullet cross-section. In the case of the floor speed, the speed at which the target hits is primarily under discussion, because the penetration performance of a floor through a plate target varies in addition to the floor mass with the floor speed, with the exponent of the variable (speed) in the range between 1.5 ./. 1.8 is to be set.

The increase in bullet speed is only due to a reduction of the projectile mass possible (if the development of the propellant powder remains unconsidered). A significant reduction in floor mass a corresponding reduction in the floor diameter is also necessary, since that Bullet weight varies with the third power of the bullet diameter. The another way to increase the breakthrough performance is to increase the mass per unit area of the cross section. You can by different constructive measures can be brought about.

The simplest method is the full floor. Then comes the full floor, that is made of a material with a high specific weight is. The dominant increase is the extension of the floor (rod or arrow projectile). This can consist of alloy steel or as a steel bullet with a hard or heavy metal core or also as heavy metal storey designed in monoblock construction.  

Floor development in the historical process:

First, a spin-stabilized sub-caliber floor with hard metal core introduced. The missile diameter was about half the tube knife. The twist angle in the launch tube was 10 ° (about double Value like a full-caliber bullet). The one disadvantage of the swirl stabilizer Sized sub-caliber floor is that the swirl speed fall with the pipe diameter increases with the same swirl angle and the same floor speed. That means a small ratio: storey to Pipe diameter requires a helix angle with a larger slope.

The other but serious disadvantage of spin-stabilized projectiles is that these bullets only through to a bullet length of up to about 5.8 caliber the swirl can be stabilized. So that's the other parameter for the breakdown performance, large mass per floor cross section, limits ge puts.

This knowledge and the increase in tank strength led to the development the sub-caliber stick or arrow projectiles, which are made of smooth (not ge drawn) launch tubes are shot. The smooth pipe is required that the projectile rotation around its longitudinal axis negatively affects the target performance flows.

In view of the much better penetration of sub-caliber Arrow projectiles compared to the spin-stabilized sub-caliber projectiles, the so-called APDS projectiles, arrow projectiles have now also been developed and manufactured in large numbers, which ver from drawn launch tubes were shot. This floor is designed as follows:

The projectile body (penetrator) is around at about two thirds of its length running grooves. In the bore of the three-part drive Cages are also arranged which engage in the grooves on the penetrator fen and thereby a rigid connection in the axial direction between the blowing Make the cage and penetrator. The tripartite cage is made by locked a retaining ring. Parallel to the retaining ring is the perimeter of the drive cage is a guide tape made of nylon or a similar plastic arranges. The job of the leader tape is to keep the trains in the launch tube to seal against the hot powder gases and because of the rotatable and friction  poor arrangement to prevent the sabot from being shot because of the drawn tube, is not set in rotation. After the floor exit tear the retaining ring and the guide band and the air resistance separates then the sabot segments from the penetrator, which then specified on the NEN trajectory flies to the target, while the individual sabot segments beforehand in different directions and at a considerably shorter distance Open the pipe mouth on the floor. With this concept it is it often happened that the guide band is not as intended in the groove on Sabot slipped, causing the projectile to rotate. A Impairment of the hit performance is then the result. Also with that Nylon guide tape does not always seal against the combustion gases ensures. The resulting gas slip increases the erosion in the drain shot tube. Also the separation of the segments from the penetrator after the floor leakage is not always trouble-free.

The object of the invention is therefore to create a projectile in which:

• - The separation of the drive cone from the penetrator after the projectile exit without The bullet trajectory is disrupted,
• - sealing the projectile in the launch tube against the hot powder or combustion gases is guaranteed.

According to the invention, this is solved as follows. Because of the different Diameter from the missile and launch tube to seal the missile construction part required against the cargo space - driving device - is part of the same strength, rotationally symmetrical, with about trapezoid shaped cross section and central bore. The outer contours are similar to a cone, hence the name "driving cone". This drive cone is divided into several segments of the same size. To the seg The guide ring is arranged just around the corner and is strong with the segments conclusively connected. The trains intersect when the projectile is fired the launch tube in the guide ring and the drive cone is at the tube passage of the floor (here: floor = flight floor and driving cone) in Rotation offset. The centrifugal or Centrifugal forces act in a radial direction on the individual driving cone Segments and thus also on the guide band. Because the bullet speed  The bullet rotation increases with the passage of the pipe and depending on it the centrifugal force squared. That is, ever the closer the projectile is to the mouth of the launch tube, and so on the greater the contact pressure of the segments on the guide belt and thus also on the pipe wall. This means that the trains are constantly re-sealed Pipe run instead.

After the projectile exit, the inner tube wall does not offer the guide ring Resistance more, and that on the drive cone segments and the guide ring acting centrifugal force tears the guide ring and creates a radial acceleration of the segments and the individual parts of the guide ring and separates them from the missile. The flight floor then flies on the predetermined trajectory to the target while the segments are on uncontrolled Open trajectories much earlier in front of the pipe mouth.

The shaft of the missile is in an area with circumferential grooves or provide grooves. In the central bore of the driving cone are also Grooves of the same cross section made. The missile is in fixed in the axial direction with the driving cone, while it is tangential Direction is freely movable. It is therefore rotatably mounted in the driving cone. With low-friction storage of the missile in the drift cone a silicone placed between the grooves of the driving cone and the missile layer or, if between the grooves of the missile and the driving cone roller body-ball or rollers are arranged, then the rotating Drift cone no serious amount of speed of rotation on the Flugge shot transferred when passing through the pipe.

According to a further feature of the projectile according to the invention, the circumferential grooves on the missile and the driving cone with a pitch angle be provided in the axial direction. The flight floor then sets the screw and the drive cone is the mother piece. The pitch angle on the missile points in the same direction as the twist angle in the launch tube. Is the Tangent of the angle equal to the coefficient of friction between the missile and driving cone, then the component is generated circumferentially from the during the coating phase of the projectile reacting on the missile force a torque on the missile of the same size, but  in the opposite direction, like the moment that results from the friction between Missile and propelling cone are created by the reaction force when firing. This means that when the bullet passes through the floor, the flight floor does not Speed of rotation about the longitudinal axis and the speed of rotation the drift cone is not transferred to the missile. Is the slope If the angle is larger, the flight floor will experience a rotating speed against the direction of rotation of the drive cone. If the tangent of the slope angle does not reach the size of the coefficient of friction, then experiences the missile a speed of rotation in the direction of rotation of the driving cone during pipe run.

Advantages:

• - Better hit performance, since the process of separating the driving cone from the flight floor no disturbing torques are transmitted to the missile. This construct principle has been used for spin-stabilized sub-caliber bullets Proven a million times over.
• - Lower driving cone weight
  This advantage can be used to increase the speed of the missile or to increase the weight of the missile.
• - Better sealing of the projectile in the launch tube
  This results in smaller gas slippage combined with less erosion in the launch tube and increased bullet speed.

Imaginary disadvantages:

• - Due to the screwing movement in the firing direction of the driving cone on the floor body when passing through the tube shortens the effective length of the launch pipe for the amount of "3".
• - The rotational speed of the driving cone generates kinetic energy in it stored, which does not translate into the speed of the flight floor.

However, these disadvantages are eliminated from the advantages and are therefore imaginary. The projectile according to the invention is illustrated by way of example in Fig. 1 to Fig. 5.

Fig. 1 and Fig. 2 - side view of the missile with propellant cone

Fig. 3 - side view of the missile (penetrator)

Fig. 4 - front view of the driving cone

Fig. 5 - side view of the driving cone

To Fig. 1
Here the flight floor 1 with the driving cone 2 is shown in a side view. The cone 2 in section and the tail unit 7 in partial section. The driving cone 2 is in the initial position.

To Fig. 2
The missile 1 with the driving cone 2 is shown here in a side view. The driving cone 1 is shifted forward by the amount 3 by the screwing movement of the driving cone 2 when the pipe passes and is located shortly before the separation process after the outlet from the mouth of the launch tube.

To Fig. 3
The missile 1 is shown here in side view in partial section.

To Fig. 4 and Fig. 5
The driving cone 2 is shown here in front and side view.
List of reference numbers

1 - Missile
2 - Driving cone
3 - Lead section of the driving cone
4 - guide ring
5 - gag groove
6 - centering rib
7 - tail unit
8 - tracer
9 - Storey hood
10 - punch block
11 - pre-penetrator
12 - predetermined breaking point in the guide ring
13 - predetermined breaking point in the driving cone
14 - Interfaces of the driver cone segments
15 - driving cone segment
16 - Direction of reaction force on launch
17 - Component of the reaction force in the circumferential direction

Claims (5)

1. "Propelling cone arrow projectile with centrifugal propellant separation", consisting of the sub-caliber (caliber = diameter), leitwerksta bilized flight projectile ( 1 ) (penetrator) and the propelling cone ( 2 ) with guide ring ( 4 ), characterized in that when firing - at Passing through the projectile ( 1 ) through the drawn launch tube - the guide ring ( 4 ) is set in rotation about its longitudinal axis (swirl) and it transmits it fully to the driving cone ( 2 ) that after the projectile ( 1 ) emerges the mouth of the launch tube which by the rotation of the propellant cone ( 2 ), which is divided into several segments ( 15 ), resulting centrifugal or centrifugal forces, the individual propellant cone segments ( 15 ) in the radial direction from the missile ( 1 ), against the resistance of the Guide ring ( 4 ), remove that then the missile ( 1 ) flies alone on the specified trajectory to the target and the individual segments ( 15 ) of the driving cone ( 2 ) and the torn ne guide ring ( 4 ) on trajectories in different directions with considerably shorter ranges from the mouth of the launch tube. 2. propelling cone arrow projectile with centrifugal propellant separation according to claim 1, characterized in that the flight projectile ( 1 ) when passing through the tube has a substantially lower rotational speed about its longitudinal axis, in the same direction of rotation, it drives as the propelling cone ( 2 ). 3. propellant cone Arrow projectile according to claim 1, characterized in that the projectile (1) undergoes a substantially lower rotational speed in the same direction in the tube passage as the drive cone (2) and in that flight projectile (1) and propellant cone (2) thereby tion movement relative Transla perform to each other. 4. propelling cone arrow projectile according to claim 3, characterized in that the direction of rotation of the missile ( 1 ) and propelling cone ( 2 ) runs counter to sets. 5. propelling cone arrow projectile according to claim 1 to 4, characterized in that the missile ( 1 ) rotates around the longitudinal axis when passing through the tube with the rotational speed = 0.