NO152063B - PROJECTILE WITH KINETIC ENERGY. - Google Patents

Abstract

1. A process for opening the launch sabot used for propulsion and guidance of a kinetic energy sub-projectile (1) of the Armor Piercing, Fin Stabilized, Discarding Sabot (AP.FS.DS) type with a sabot (4) comprising several components (4a, 4b, 4c), characterized by the fact that the opening takes place in two main phases : a first phase consisting of the sabot aft section opening through the discarding of the components while the fore section is still locked, and a second phase consisting of the fore section opening after full unlocking of the components, the opening of the aft section being followed up by the separation of the sub-projectile (1) from the sabot fore section.

Description

The present invention relates to a

device which makes it possible to open a launch case used for firing an under-caliber projectile of the arrow type by means of an optional rifled tube.

Due to their particularly high yield, arrow ammunition has proven to be remarkably effective for attacks on armored targets such as armored vehicles. Their performance is a consequence of their very high speed, their relatively significant mass produced by the use of high-density materials, and their negligible impact surface. These different factors make it possible to achieve a kinetic energy and a surface energy upon impact that is very high and necessary for rebound in modern reinforcements.

The use of this type of ammunition as an anti-tank projectile necessitates the execution of the launch with maximum precision in order to increase the probability of hitting a vital place on the enemy vehicle and destroying it as quickly as possible to avoid any counterattack.

Apart from the problems of sighting, the precision of the launch depends mainly on the ballistic properties of the projectile and especially on the conditions under which the separation of the launch case takes place.

In reality, two types of devices are used for launching arrow projectiles.

The most classic device consists in the use of a launch sleeve which is formed by several elements that surround the arrow, held by means of one or two belts in contact with the launch tube. The front part of this type of tube comprises an extended surface in such a way that the elements of the sleeve can be removed under the action of the aerodynamic forces caused by the air resistance at the exit of the launch tube. Thus, for this type of ammunition, the launch sleeve will open from front to back by pressing against the arrow, which can be destructive to shot precision due to the fact that the elements of the sleeve can collide with the arrow's guide fin tail and thus disrupt the desired trajectory and cause the shot to scatter. Another problem is due to the fact that the separation of the sleeve's elements does not always take place at the same time, which produces a transverse impulse on the arrow and damages launch precision.

the tion.

The device described in French patent 2,445,509 makes it possible to eliminate some of the previously known problems. In this case, it concerns an ejector sleeve made of an alloy with high mechanical strength and equipped with a sealing band or belt against the weapon's propellant gas, where the central part of the surface that lies next to the projectile is equipped with a steel disc in contact with the projectile's guide fins and the circumference of which includes hoops, in which a set of clamps is pivotally attached which can be unfolded radially. These clamps consist of rigid plates and are on the one hand in contact with the launch tube and on the other hand they hold the pellet body axially. There is also a locking device for these plates for part of the arrow's guide fins.

A significant disadvantage of this type consists in its complexity, which makes production difficult in large series and entails high costs. On the other hand, the presence of the hoops, the joint connections and the moving parts are hardly compatible with the required precision, above all considering the significant accelerations used during the internal ballistic phase.

Another disadvantage comes from the fact that this type of device only allows firing of the arrow according to the "ejection" principle, which entails very large compression forces on the rear part of the arrow body and which can break up or support the appearance of incipient cracks in the penetration body, which are unfavorable for penetration into the target area. It should also be noted that the principle of launching by "ejection" is detrimental to the precision of the launch provided that the impinging vector component is located as far back as possible on the projectile.

The task to be solved with the help of the present invention is to provide a

launch device which has the advantages of classic launch casings, but which makes it possible to achieve very little dispersion during the launch and at the same time eliminates, firstly, that the elements of the casing rest against the arrow during the phase of separation and, secondly, the possible impact of these same elements against the steering fins, and at the same time ensure the separation of

the elements from the projectile part and allow the application of the ejection principle "ejection" or "towed ejection".

The present invention is thus aimed at a device for opening the launch sleeve and is characterized by the features that appear from the characteristics in the subsequent claims.

A particular embodiment of the invention will now be described as an example with reference to the schematic drawings, where fig. 1 is a longitudinal section along the line A-A in fig. 2 and shows the projectile as it leaves the launch tube, fig. 2 is a view seen in the direction of arrow F in fig. 1, fig. 3 is a longitudinal view showing the first phase during opening of the sleeve, fig. 4 is a view seen in the direction of the arrow F in fig. 3, fig. 5 is a longitudinal view showing the second phase during opening of the sleeve, fig. 6 is a view seen in the direction of the arrow F

fig. 5 and fig. 7 is a longitudinal view showing the final phase during the separation of the sleeve.

Fig. 1 shows in thin lines the arrow 1 equipped with its guide fins 2 on the tail section, below the exit of the launch tube 3. The launch sleeve 4 comprises three elements 4a, 4b and 4c in contact with the arrow by means of screw threads 5 which allow the transmission of the driving forces.

The sleeve 4 consists firstly of a pressure plate 6 which is exposed to the pressure from the propellant gases and secondly of a guide plate 7 used to guide the projectile in the launch tube.

The plates 6 and 7 are attached by means of a tubular part 8 which extends backwards from the pressure plate 6 with the part 8a and at the height of the guide plate with the part 8b.

According to a technique known to those skilled in the art, the seal between the launch tube and the sleeve itself is produced by means of a sealing band 9 placed in a circular recess 10 arranged on the pressure plate. In the device according to the invention, this band also has the task of ensuring the rear connection and locking of the elements of the sleeve. A ring 11 is arranged in a circular groove 12 arranged in the interior of the guide plate 7. This band ensures retention and connection of the front part of the elements of the sleeve. A release 13 is prepared concentrically to the threads in connection 5. This release

13 provides a clearance between the projectile and the launch sleeve, which clearance has a function to be described later. The function when opening the sleeve for this projectile is as follows. At the exit of the launch tube 3, the propellant gases represented by the arrows 14 exert pressure on the rear part of the sleeve elements. This pressure has the effect of causing an opening at the rear part of the sleeve's elements, while the front part of these is still locked by means of the ring 11. When the forces exerted on the rear part of the sleeve, are sufficient, the sealing band 9 is broken and allows opening at the rear part. In the case of a launch by means of a fluted or slightly fluted tube, the centrifugal forces will cooperate with the action of the pressure from the propellant gases to cause the opening of the sleeve at the rear part and to break the locking produced by the band 9. I in the latter case, it can be seen that the front ring is not exposed to the centrifugal effect because it is located in an annular groove arranged in the interior of the guide plate 7. The opening of the rear part of the launch sleeve is realized by rotation about the axis 15 which passes through the rotation point 16 shown in fig. 4. During this opening of the rear part, the front ring is exposed to tensile and bending forces used to break it (fig. 3). This break is realized when the rear optimal opening angle is achieved and it happens at the location of the rotation point 16. To facilitate this break, break instructions can be arranged on the front ring 11. The opening of the rear part is immediately followed by the separation of the sleeve from projectile (see fig. 3 and 4). For this purpose, the pivot point 16 is located in front of the front end of the tubular part 8b. This separation is also favored by the presence of the release 13 prepared in the interior of the tubular part 8b. In fig. 4 it can be seen how the separation 17 of the sleeve from the arrow takes place during the rear opening phase.

When the front connection produced by the ring 11 is broken, the aerodynamic pressure 18 due to the projectile's speed will generate radial forces on the elements of the sleeve. These forces allow opening of the front part (see fig. 5 and 6) and then complete ejection of the sleeve (see fig. 7).

Since the opening of the rear part of the sleeve takes place without support against the projectile, this provides a significant advantage that allows a surprising improvement in shooting precision because the arrow is not exposed during opening of the sleeve to noticeable shocks that could increase dispersion.

Claims (7)

1. Arrow-type kinetic energy projectile propelled by means of a launch sleeve (4) comprising several elements and consisting of a tubular portion (8) surrounding the arrow (1), a first plate (6) referred to as a pressure plate arranged near it rear part of the tubular part (8) and exposed to the pressure from the propellant gases and another plate (7) designated guide arranged near and in front of the tubular part (8), characterized in that the sleeve (4) comprises connecting means (9, 11 ) between the elements (4a - 4c), which bodies are placed firstly on the front part (7) of the sleeve (4) and secondly on the rear part (6) and that the connecting bodies (9, 11) are dimensioned and arranged so that the members (9) on the rear part (6) are broken before the connecting members (11) for the front part (7) so that the sleeve (4) is opened from the rear and forwards. 2. Projectile according to claim 1, characterized in that the members (11) are dimensioned and arranged so that the front connection of the sleeve is broken under the action of the opening of the rear part (6) of the sleeve (4). 3. Projectile according to one of claims 1-2, characterized in that the means (9) for connecting the rear part (6) consist of a band that surrounds the pressure plate (6). 4. Projectile according to one of claims 1 - 3, characterized in that the members (11) for connecting the front part (7) of the sleeve (4) consist of a ring placed at the height of the guide plate (7). 5. Projectile according to one of claims 1-4, characterized in that the pivot point (16) for the elements is located in front of the front end of the tubular part (8) which surrounds the arrow (1). 6. Projectile according to one of the claims 1-5, characterized in that the pivot point (16) for the elements is located in front of the ring (11) which forms the connecting elements for the front part (7) of the sleeve (4). 7. Projectile according to one of the claims 1-6, characterized in that the front ring comprises fracture indications placed above the adjacent surfaces of the sleeve (4) elements.