FR2988827A1 - Projectile for neutralizing individual, has runner passing from back position occupied by runner during shooting towards front position at time of impact on target, where runner comes to impact with body part in direct or indirect manner - Google Patents

Abstract

The projectile (1) has a rigid body (3) and a head (2) that is made out of flexible material, and is connected to the body. A runner (5) is allowed to slidingly rise with regard to the body, where the runner is able to pass from a back position that is occupied by the runner during shooting towards a front position at the time of impact on a target. The front position is provided as the position in which the runner comes to impact with a part (9) of the body in a direct or indirect manner. A compressible material block is interposed between the runner and the body.

Description

The technical field of the invention is that of non-lethal projectiles and ammunition firing such projectiles. Non-lethal projectiles are well known today. 5 They allow the police to neutralize an individual without killing or seriously injuring him. US6041712 discloses a reduced lethal projectile which comprises a deformable foam nose integral with a rigid plastic skirt. 10 The nose crashes on the individual thus reducing the risk of injury. The deterrent effectiveness of this projectile is related to the impulse received, ie the amount of movement of the projectile that is stopped by the individual. It therefore depends on the mass of the projectile and its speed. However, the shock received creates a peak of force that can be significant despite the deformable foam nose. These known projectiles can therefore be dangerous during an impact on a fragile part of the individual, such as the head. It is an object of the invention to provide a reduced lethal projectile for decreasing the force transferred to the target upon impact while maintaining the level of the received pulse. The projectile proposed by the invention can thus retain a strong deterrent effect while being less dangerous to use. Thus, the subject of the invention is a reduced lethal projectile comprising a head made of flexible material connected to a rigid, projectile body, characterized in that it comprises at least one flyweight which is slidably mounted relative to the body, the flyweight being able to pass a rear position that it occupies when firing towards a forward position when impacting a target, a forward position in which it directly or indirectly impacts a part of the body. According to one embodiment, the body comprises a rear bore inside which is housed a cylindrical weight 5. According to another embodiment, the weight is shaped into a base within which the body can slide. The weight may be bonded to the body by at least one shearable calibrated connection means. Moreover, the weight may be connected to the body by at least one damping means, such as a spring. According to another embodiment, the projectile may comprise a block of compressible material interposed between the flyweight and the body, a block that the flyweight will impact in its forward position. According to another embodiment, the projectile may comprise a locking means of the flyweight in its rear position. The locking means may for example be constituted by an extractable pin. Other advantages of the invention will appear on reading the following description of various embodiments, a description given with reference to the appended drawings and in which: FIGS. 1a and 1b show in section a first embodiment of the invention; of a projectile according to the invention, FIG. 1a showing it at rest and FIG. 1b at impact on a target; FIG. 2a is a comparative graph showing the evolution of the force of impact on a target for a projectile according to the prior art and a projectile according to the invention, - Figure 2b is a comparative graph showing the evolution of the pulse received by the target for a projectile according to the prior art and a projectile according to the invention, - Figure 3 shows in section another embodiment of a projectile according to the invention, - Figure 4 shows in section another embodiment of a projectile according to the invention, - the Figure 5 shows in section another mode of 10 shows a section of another projectile according to the invention; FIG. 7 shows in section another embodiment of a projectile according to the invention; FIG. FIG. 8 shows in section an ammunition incorporating another embodiment of a projectile according to the invention. With reference to FIGS. 1a and 1b, a reduced lethal projectile 1 according to one embodiment of the invention comprises a head 2 made of flexible material, for example compressible foam or elastomer, which head is connected to a body 3 rigid, for example aluminum or a plastic material such as polyamide. The head 2 is connected to the body 3 by gluing. FIG. 1a shows a pin 3a for positioning the head 2 on the body. Such a nipple can of course be omitted. The body 3 comprises an internal bore 4 having a cylindrical wall 4a, bore inside which is slidably mounted a flyweight 5. The flyweight 5 is held at its rear by a collar 6 of the body 3. This collar 6 can be performed by deformation of the material of the body 3 during assembly. The weight 5 is held in place in its rest position, for example by placing an adhesive point 7 between the weight and the body, at the rear portion of the weight 5. FIG. same projectile 1 to the impact on a target 8. The shock on the target causes first deformation of the nose 2 of the projectile. However, the weight 5 is decoupled from the body 3 of the projectile by breaking the point of glue 7. The force received by the target is therefore less because it results from the effect of the sole mass of the body 3 and the nose 2.

The weight 5 moves by inertia and goes from its rear position that it occupied during firing (Figure la) to a forward position in which it directly impacts the bottom wall 9 of the bore 4 of the body 3. This impact occurs less than one millisecond after the impact on the target. Figure 2a shows the force F received by the target as a function of time t. Curve 10 shows the variation of this force for a projectile according to the prior art, comprising a solid rigid body (without flyweight) and a nose 20 foam. A single peak of force F2 occurs during the impact. It is of the order of 40 to 50 kilo Newton for a projectile of caliber 40 mm (mass of 30 to 60 grams) impacting a wall with a speed of the order of 75 to 95 m / s. Curve 11 shows the variation of the force with a projectile according to the invention. This projectile also has a nose foam, having the same overall mass as the projectile according to the prior art and is fired at the same speed. Note that there are two consecutive peaks of forces P1 and P2. The first P1 corresponds to the impact of the projectile on the target, the second P2 corresponds to the impact of the weight 5 on the body 3 of the projectile.

Note also that the maximum amplitude Fl of the force received by the target is substantially divided by two with the invention. Figure 2b shows the variation of the pulse I received by the target as a function of time. The curve 12 corresponds to the projectile according to the prior art and the curve 13 to the projectile according to the invention. It is found that the pulse received is substantially the same which is logical since the masses of the projectiles 10 are the same and the speeds also. Thanks to the invention the deterrent power of the projectile is the same because the shock received remains of the same order. On the other hand, the wounding effect is greatly reduced because the force applied to the target is reduced. The curve 11, characteristic of the force, can be modified by various means. It is thus possible to choose a different ratio between the mass of the weight 5 and the mass of the body 3. This will have the effect of giving a different amplitude for each of the peaks P1 and P2. It is also possible to provide damping means or at least one spring between the weight 5 and the body 3. This will have the effect of temporally removing the peaks P1 and P2. Different projectile architectures are possible to obtain such characteristics. Figure 3 shows a projectile 1 in which the bore 4 is closed at its rear by a screwed cap 14. A tension spring 15 is fixed to the plug 14 and the flyweight 5. The spring 15 ensures by its stiffness a maintenance 30 of the flyweight 5 away from the bottom wall 9 of the bore 4 of the body 3. A the impact on a target, from a certain level of deceleration, the weight 5 stretches the spring 15 and impacts the bottom wall 9. The spring 15 is a shock absorbing means. The deformation of the spring 15 consumes some of the kinetic energy of the projectile. This results in a temporal spacing of the two force peaks P1 and P2.

FIG. 4 shows another embodiment in which a compression spring 16 is interposed between the weight 5 and the bottom wall 9 of the body 3. As in the first embodiment, the weight 5 is held at its rear part by a flange 6 of the body 3. The operation is similar to that described with reference to FIG. 3. At the impact on a target, from a certain deceleration level, the weight 5 compresses the spring 16 and comes to impact the bottom wall 9 (indirectly through the spring 16 completely compressed). The deformation of the spring 16 consumes some of the kinetic energy of the projectile. This results in a temporal spacing of the two force peaks P1 and P2.

FIG. 5 shows another embodiment in which the weight 5 is connected to the body by shearable connecting means 18. This is two radial pins 18 which pass through the annular wall of the body 3 and are housed in holes of the weight 5.

These pins 18 are calibrated to be sheared only for impact resulting in a certain level of deceleration. Thus, if the projectile is fired on a soft target, the weight 5 may remain integral with the body 3 and the behavior of the projectile will be similar to that of the known projectiles. If the projectile impacts against a hard target, for example the head of an individual, the more violent braking causes the shear pin 18 and causes the separation of the weight 5 and the body 3. The effort received by the target is then less than a limit value which is easily calibrated by the definition of the pins and the stress characteristic comprises the two peaks P1 and P2 as previously described. FIG. 6 shows another embodiment which differs from that of FIG. 5 in the presence between the bottom wall 9 and the weight 5 of damping means which consists of a block of compressible material 17. This block 17 performs the same functions as the spring 16 of the mode according to Figure 4. The block 17 is interposed between the weight 5 and the bottom wall 9. It is compressed by the weight 5 and can consume some of the energy 15 kinetics of the projectile. This results in a temporal spacing of the two force peaks P1 and P2. The block 17 can be made of synthetic foam, elastomer or even metal foam, for example aluminum foil. The compressibility characteristics 20 of the material of the block 17 will be chosen as a function of the force characteristic which is sought at impact. FIG. 7 shows another embodiment of the invention in which the body 3 is cylindrical and slidably mounted in a bore 19 having a cylindrical wall 19a 25 arranged in a feeder 5 which is here shaped in a base for the projectile 1 Shearable pins 18 are interposed between the weight 5 and the body 3. A compression spring 16 is interposed between the rear wall 9 of the body 3 and the bottom 30 of the bore 19 of the weight. Impact operation is similar to that described previously. Finally, FIG. 8 shows a complete ammunition 21 associating a projectile 1 according to the invention and a case 22 enclosing a propellant charge 23 and carrying an igniter 24. The projectile 1 comprises a sliding flyweight 5 which is separated from the rear wall 9 of the body by a compression spring 16. This projectile differs from the previously described projectiles in that it comprises a locking means 25 of the weight 5 in its rear position. This locking means 25 is constituted by an extractable pin which passes through the annular wall of the body 3 and against which bears the flyweight 5. It is then possible operatively to remove or not the pin 25 before firing. When the pin remains in place, the reduced lethality projectile imparts significant force to the impact on a hard target. This can be interesting operationally if one wishes to use the projectile to clear an obstacle or open a door. If the pin 25 is removed before firing, the projectile 20 operates according to the modes previously described. The impact force is reduced and the reduced lethality is guaranteed. Other embodiments are possible. In particular, it is possible to combine the different characteristics of the modes described above.

For example, an extractable pin 25 may be associated to immobilize the flyweight 5 in all the embodiments of FIGS. 1 to 7.

Claims (8)

CLAIMS1- Reduced lethal projectile (1) comprising a head (2) of flexible material connected to a body (2) rigid, 5 projectile characterized in that it comprises at least one flyweight (5) which is slidably mounted relative to the body (3), the flyweight (5) being able to pass from a rear position which it occupies when firing to a forward position when impacting a target, a forward position in which it directly or indirectly impacts a part (9) of the body (3). 2- reduced lethal projectile according to claim 1, characterized in that the body (3) has a rear bore (4) within which is housed a cylindrical weight 15 (5). 3- reduced lethal projectile according to claim 1, characterized in that the weight (5) is shaped as a base within which the body (3) can slide. 4-reduced lethal projectile according to one of claims 2 or 3, characterized in that the weight (5) is connected to the body (3) by at least one connecting means (18) calibrated shearable. 5-reduced lethal projectile according to one of claims 2 to 4, characterized in that the weight (5) 25 may be connected to the body (3) by at least one damping means (15,16), such as a spring. 6- reduced lethal projectile according to one of claims 2 to 4, characterized in that it comprises a block of compressible material (17) interposed between the flyweight (5) and the body (3) block (17) that the flyweight (5) impacts in its forward position. 7- reduced lethal projectile according to one of claims 1 to 6, characterized in that it comprises a locking means (25) of the weight in its rear position. 8- reduced lethal projectile according to claim 7, characterized in that the locking means is constituted by an extractable pin (25).