FR2950688A1 - Projectile for reduced lethal weapon, has core provided with rear end and front end, where rear end is assembled with front wall of cup, and external envelope covering front end of core - Google Patents

Abstract

The projectile (1) has a rear end (2) provided with an axial opening cavity (3), and a front end (4) formed in shape of spherical shell. A cup (5) is provided with a cylindrical tubular wall (8) that is closed by a front wall (9), where the front wall is transversely arranged to a longitudinal axis (L). A core (6) is made of aluminum foam and thermoplastic material, and is provided with a rear end (13) and a front end (16), where the rear end is assembled with the front wall of the cup. An external envelope (7) covers the front end of the core, and is made of thermoplastic foam.

Description

The present invention relates to projectiles for a weapon with reduced lethality, capable of impacting a target as would a violent punch while limiting the damage or trauma induced by this impact, particularly on the sensitive and unprotected areas of an individual (especially the head).

ALR (Reduced Lethal Weapon) projectiles are typically used by law enforcement and armed forces in external operations to neutralize or scare off certain individuals, while avoiding harm to them or minimizing injuries or injuries caused. These projectiles are fired by means of launchers with striped tube of which the most current are with the caliber of 40 mm (designation NATO: 40 mm X 46). Very generally, these ALR projectiles have a generally cylindrical shape whose length is of the order of 50 to 70 mm and whose diameter, as specified above, is of the order of 40 mm, with a front end in the form of a cap in general half spherical. They are conventionally made by molding thermoplastic foam. Today the state of the art is quite poor in the field of kinetic ammunition reduced lethality (LR) and in particular in improving the terminal effect of the corresponding projectiles. Indeed, previous achievements have striven to make more ductile materials constituting these projectiles thinking that the more the projectile is "soft" less it is lethal. To the applicants' knowledge, no concrete reflection has been made on the understanding of the relationships between physical parameters and lesional effects during the impact of an LR projectile on a human target. The identification of the "good" physical parameter makes it possible to search for relevant technological solutions.

To meet this objective, a study was carried out and demonstrated and validated by tests and stimulations: - that energy is not the universal mechanical parameter of severity - that this parameter is in fact the force at impact . It is recalled that the control of the low probability of provoking a lethal outcome with a reduced lethal projectile, serious injury or permanent injury to an individual is not easy to obtain because of a physical phenomenon well known to ballists. which is the loss of velocity on the trajectory of the projectile, caused by the resistance of the air to the advancement of the latter. Thus, with the current projectiles, one could have a very low level of efficiency at a distance of 50 m and a level of deleterious effects important to 10 m, which poses enormous employment problems for the forces of the order and the armed forces.

As stated above, the physical parameter that is important to the impact in terms of lesional effects is the impact force on the target. To improve the efficiency and non-lethality of reduced lethal projectiles, the main objective of the invention is to transmit to the impact a programmed force that is always the same, or substantially the same, regardless of the terminal speed and correlatively regardless of the firing distance (this in the conventional speed ranges at the moment of impact (that is to say between about 50 and 100 m / s) For this, the ALR projectile according to the invention, which has a generally cylindrical shape of longitudinal axis L, comprising a rear end provided with a axial outlet cavity and a spherical or approximately spherical cap-shaped front end, is characterized in that it comprises: a base comprising a cylindrical tubular wall centered on said longitudinal axis; ngitudinal L, which tubular wall is closed by a front wall disposed transversely to said axis L, said tubular wall and said front transverse wall delimiting said opening rear cavity, - a core made of aluminum foam, which core has a generally cylindrical shape centered on said axis L, comprising a rear end and a front end, which rear end is assembled with said front wall of the base and which front end is shaped spherical or substantially spherical cap. an outer envelope covering at least the front end of said core. The base of the projectile is deformed during firing by the scratches of the barrel of the weapon which allows the rotation of the projectile. The aluminum foam core is very lightweight and offers very interesting crushing and energy absorption characteristics, homogeneous and independent of the rate of deformation in all directions; the outer casing makes it possible to optimize the ballistic flight of the projectile and to attenuate the first projectile-target contact at the moment of impact. The impact force of this projectile is constant or almost constant regardless of its speed (in conventional impact velocity ranges, especially between 50 and 100 m / s). This impact force is in particular a function of the density of the aluminum foam, a parameter chosen according to the desired impact force. Preferably, the density of the aluminum foam used for the core of the ALR projectile according to the invention is between 30 and 300 kg / m3. The projectile base is advantageously made of thermoplastic material and its thermoplastic foam envelope.

According to an interesting characteristic, the tubular wall of the base comprises an annular outer annular ring which extends at least in part opposite its transverse front wall. According to a particular embodiment, the tubular wall of the base extends beyond the front transverse wall to form a housing for receiving the rear end of the aluminum foam core. According to another particular embodiment, the transverse wall of the base is extended forward by an axial pin allowing the centering of the front part of the projectile.

According to yet another feature, the outer casing extends to the base to cover the entire exposed face of the core. On the other hand, the core may comprise an axial recess opening into its rear face facing the front transverse wall of the base. This recess in particular makes it possible to program two levels of impact force by selecting two densities of the aluminum foam. It can remain as is or be filled by a more or less dense aluminum foam, to program the severity of the shock. According to another particular embodiment, the projectile comprises an annular narrowing between its front and rear ends, corresponding to a decrease in diameter, which narrows extends forwardly from the front end of the base.

This particularity is intended in particular to avoid contact of the base in inclined shock with the target. The base, the core and the outer shell of the projectile are made independently and they are assembled together by any appropriate means, especially by gluing.

The invention will be further illustrated, without being limited in any way, by the following description of several possible embodiments, given solely by way of example and shown in the accompanying drawings, in which: FIG. 1 is a perspective view of an ALR projectile according to the invention; FIG. 2 is an axial sectional view of the projectile of FIG. 1; - Figure 3 is an axial sectional view of a first embodiment of the projectile according to the invention; FIG. 4 is a perspective view of a second variant of the projectile according to the invention; FIG. 5 is an axial sectional view of the projectile of FIG. 4; FIGS. 6 and 7 are curves illustrating the variation of the force during the impact as a function of time for projectiles according to the invention.

The projectile ALR 1 illustrated in Figures 1 and 2 has a generally cylindrical longitudinal axis L. Its length may be of the order of 50 to 70 mm and its diameter of the order of 35 to 45 mm. The rear end 2 of this projectile 1 ends in a plane perpendicular to the longitudinal axis L. At this level, an axial recess 3 opening allows conventional reception of a pyrotechnic propulsion cartridge, or other mode of propulsion. Its front end 4 is shaped spherical cap or approximately spherical. This projectile 1, symmetrical around its longitudinal axis L, consists of a rear base 5, extended forwardly by a core 6 whose outer face is substantially completely covered by an envelope 7. The rear base 5 has a wall cylindrical tubular 8, centered on the axis L, which is closed at its front end by a transverse wall 9. The tubular wall 8 is not closed towards the rear, and, with the front transverse wall 9, it delimits the axial recess 3 above.

Opposite this transverse front wall 9, it is noted that the tubular wall 8 comprises a one-piece annular ring 10 which projects outwardly. The outer surface of this ring 10, of generally cylindrical shape, defines the maximum external size of the projectile and constitutes a guide face inside the barrel of the propulsion weapon.

The outer surface of the tubular wall 5 has a diameter a few millimeters smaller than that of the guide surface of the one-piece ring 10. On the side of the face 11 facing the front end 4 of the projectile, the transverse wall 9 of the base 5 comprises a cylindrical monobloc stud 12, centered on the axis L. This pin 12 has a diameter of the order of half the diameter of the projectile 1; its height is a few millimeters. The base 5, comprising the tubular wall 8, the transverse wall 9, the ring 10 and the pin 12, is made in one piece by molding thermoplastic material. The density of the thermoplastic material used may be of the order of 1200 to 1600 kg / m 3. Its function is to give the projectile a large part of its mass, to allow its propulsion and the connection to the front of the energy absorbing part and programming the impact force. The core 6 of the projectile 1 has a generally cylindrical overall shape centered on the axis L. Its rear end 13 has a diameter slightly smaller than the diameter of the guide surface of the ring 10 of the base 5, and its rear face 14 is structured to marry the front face of this base 5, with the stud 12.

For this, this rear face 14 extends in the plane of the front face 11 of the base 5, and it comprises an axial reservation 15, corresponding to the shape of the stud 12. The front end 16 of the core 6 is shaped spherical or substantially spherical cap centered on the axis L.

This core 6 may have a length of between 30 and 50 mm. It is made of aluminum foam (honeycomb aluminum structure) whose density is advantageously between 30 and 300 kg / m3. The length of the core 6 and the density of the aluminum foam used are a function of the desired impact force and the amount of energy to be absorbed.

Is core 6 made by molding or any other method of forming or machining honeycomb materials. For example, an aluminum foam manufactured by CYMAT Corporation (Canada) under the designation "Cymat stabilized aluminum foam" (registered trademark), or by SHINKO WIRE CO Ltd (Japan) under the designation "Alporas" is used. " (trademark). Such a core structure 6 has the function of limiting to impact the predetermined shock force in advance during the absorption of energy, regardless of the shock velocity of the projectile. The shape at the front of this honeycomb structure also makes it possible to maintain the rise time of the impact force, up to the nominal level, below the critical bursting value of the scalp, for example. The rear end 13 of the core 6 is assembled with the front end 11, 12 of the base 5 by any appropriate means, for example by gluing. The front end 16 of the core 6 is covered by the casing 7 advantageously made of thermoplastic foam; the density of this thermoplastic foam is advantageously between 100 and 150 kg / m3. This outer casing 7 has a thickness of a few millimeters (for example 1 to 3 mm, advantageously of the order of 2 mm). In the illustrated embodiment, it covers the entire outer front and side surface of the core 6, with the exception of an annular band 18 of the rear end 13 of said core 6. So that its outer surface is in the extension the outer surface of this "free" annular band 18, the casing 7 is housed in a suitable reserve 19 formed on the outer face facing the core 6. This envelope 7, tube-shaped closed at its front end by a spherical or substantially spherical cap is fixed on the core 6 by any appropriate means, for example by gluing.

The purpose of the envelope 7 is to improve the ballistic flight of the projectile, to avoid, at the first target-projectile contact, the local bursting of the biological material of the target and to allow pre-crushing of the honeycombed aluminum structure. FIG. 3 illustrates an alternative embodiment of the projectile of FIGS. 1 and 2. The parts identical to the previous embodiment retain the same reference marks to facilitate comprehension. In the projectile 1 'corresponding, the core 6 has a blind axial recess 20 which opens into its rear face 14. This recess 20 preferably has a cylindrical shape whose diameter corresponds, with the game, to that of the axial pin 12 of the base 5 Its function is to make it possible to achieve during the shock a profile of impact force at two levels programmed in advance according to the desired severity. Still in alternative embodiments, the recess 20 can be filled by an added material. This added material may for example consist of a denser aluminum foam than that used for the periphery of the core 6, so as to increase the impact efficiency of the projectile. For this projectile 1 ', we note that the length of the core 6 is less than that of the projectile core 1 of Figures 1 and 2. Figures 4 and 5 illustrate another possible embodiment of a projectile according to the invention .

Here again, the parts identical to the embodiments of FIGS. 1 to 3 retain the same reference marks to facilitate comprehension. The corresponding projectile 1 "has a rear base 5, extended forwards by a core 6 of aluminum foam whose outer face is covered by an envelope 7.

It is noted that the tubular wall 8 of the base 5 extends forwardly, beyond the transverse wall 9, by a tubular monobloc extension 21. The guide ring 10 extends facing the transverse wall 9 of the base 5, on a portion of the tubular wall 8 and on the majority of the length of the extension 21. This extension 21 and the wall 9 of the base 5 form a housing 22 for receiving the rear end 13 of the core 6 The integral stud 12 of the previous embodiments is no longer present. Again, the core 6 and the base 5 are assembled by any appropriate means, preferably by gluing. On the other hand, in this embodiment, it is noted that the envelope 7 covers the entire exposed surface of the core 6; it extends to the base 5, and in particular to the front end of the extension 21.

The embodiment of FIGS. 4 and 5 is also distinguished from the previous ones, by the presence of a necking 23, corresponding to a decrease in diameter, between its rear ends 2 and before 4. This necking 23 has the function of avoiding in Inclined impact of the projectile contact plastic-target base, thus avoiding a level of contact force incompatible with the programming of efforts by the aluminum foam. It is essentially obtained by a diameter reduction of the rear end 13 of the core 6. The presence of the necking 23 gives the core 6 a particular longitudinal section, with a rear end 13 of cylindrical shape extended by a front end 16 in the form of bead or bulge, globally spherical. The surface of the front end 4 of this projectile 1 "is particular: the spherical end surface 4a is extended by a truncated cone surface 4b itself extended by a cylindrical surface 4c (whose diameter corresponds approximately to the diameter of the ring 10) which is further extended by a "reentrant" surface 4d leading to the constriction 23. This particular shape of the front end 4 of the projectile 1 "makes it possible to calibrate the rate of rise in force (level of the force programmed on the time taken to reach it), thus avoiding the local bursting of the biological structures (scalp for example in cranial shock). The shapes of these projectiles all have a perfect match between their center of gravity and their center of thrust to obtain good outdoor ballistics. FIG. 6 is a curve showing the variation of the force during the shock as a function of the impact time, for the projectiles 1 and 1 "of FIGS. 1 and 2, on the one hand, and 4 and 5, on the other hand. distinguishes: - the rate of rise (constant force a on the rise time b) This rate of rise must be lower than a critical value in order not to burst the biological structures of surface, - the constant level of the force has programmed by the density of the aluminum foam and the geometry of the core.This level a is calibrated to determine in advance the damage and the desired severities.-The end of the shock e, always at a constant force or substantially constant.

Figure 7 shows the force / time variation for a dual density projectile (as shown in Figure 3). The level d is obtained by the peripheral foam of the core, and

Claims (1)

1. A projectile for reduced lethality weapon, having a cylindrical general shape of longitudinal axis L, which projectile (1, 1 ', 1 ") comprises a rear end (2) provided with an axial opening cavity (3). ) and a front end (4) having a spherical or approximately spherical cap shape, characterized in that it comprises: - a base (5) comprising a cylindrical tubular wall (8) centered on said longitudinal axis L, which tubular wall (8) is closed by a front wall (9) disposed transversely to said axis L, said tubular wall (8) and said front transverse wall (9) delimiting said opening rear cavity (3), - a core (6) made of foam of aluminum, which core (6) has a generally cylindrical shape centered on said axis L, comprising a rear end (13) and a front end (16), which rear end (13) is assembled with said front wall (9) of the base (5) and which one the front end (16) is in the form of spherical or substantially spherical cap, and - an outer casing (7) covering at least the front end (16) of said core (6). 2. Projectile according to claim 1, characterized in that said core (6) is made of aluminum foam having a density of between 30 and 300 kg / m3. 3. Projectile according to any one of claims 1 or 2, characterized in that said base (5) is made of thermoplastic material. 4. Projectile according to any one of claims 1 to 3, characterized in that said outer casing (7) is made of thermoplastic foam. 5. Projectile according to any one of claims 1 to 4, characterized in that the tubular wall (8) of the base (5) comprises a one-piece annular outer ring (10) which extends at least in part opposite its front transverse wall (9). 6. Projectile according to any one of claims 1 to 5, characterized in that the tubular wall (8) of the base (5) extends beyond the front transverse wall (9) by an extension (21), to form a housing (22) for receiving the rear end (13) of the core (6) of aluminum foam. 7. Projectile according to any one of claims 1 to 6, characterized in that the transverse wall (9) of the base (5) is extended forwardly by an axial pin (12). 8. Projectile according to any one of claims 1 to 7, characterized in that said outer casing (7) extends to the rear base (5) to cover the entire exposed face of the core (6) . 9. Projectile according to any one of claims 1 to 8, characterized in that the core (6) has an axial recess (20) opening in its rear face (14) facing the front transverse wall (9) of the base (5). 10. Projectile according to any one of claims 1 to 9, characterized in that it comprises an annular narrowing (23) between its front ends (4) and rear (2), corresponding to a decrease in diameter, which shrinks (23) extends forwardly from the front end (21) of the base (5).