FR2714166A1 - Projectile with progressive braking on impact with a hard surface - Google Patents

Abstract

The projectile, containing a military payload (30), has a nose cone (10) which is deformable for a length (L) when a constant effort is applied to it, e.g. from impact with a hard surface. It also incorporates a delay system (45) which detonates the payload after a time at least equivalent to that taken for the nose cone to be crushed. The nose cone has an aerodynamic outer surface, is made from a ductile material, and has a transverse aperture (11) to graduate the deceleration. The aperture can contain a product for secondary military effects or for energy absorption, e.g. an elastomer foam or honeycomb structure.

Description

 The invention relates to the field of projectiles intended to produce either a rotting of areas or an omnidirectional dispersion of products contained in a tank of the projectile such as, for example, incendiary gels. The invention will be more particularly described in the latter case but it is nevertheless applicable each time it is necessary to progressively brake a projectile striking a hard surface.

 This need is encountered in particular in two cases.

 The first case for any projectile that we want to slow down gradually in the event of an impact on a hard surface such as a blockhouse wall so that the projectile falls at the foot of the wall without damaging its military part. The effect of the projectile can then be triggered with a random delay thus creating an area of insecurity.

 The second is encountered for a projectile intended to disperse a product contained in a tank, for example an incendiary gel.

 Naturally an incendiary projectile can also be a zone decay projectile. It suffices for this that the incendiary projectile like any rotting projectile is provided with a triggerable firing with a predetermined delay but unknown to the defender and random for him, or really random.

 In the case of the projectile used to disperse a product, in particular in the case of incendiary projectiles, the embodiment and operation are well known in the art.

 Such projectiles are described for example in the French patent application in the name of the applicant No. 89.06924 or in US patents 3,905,287 and 3,888,179.

 Known projectiles include a reservoir containing the product to be dispersed, at least one safety device and the firing of auxiliary explosives, the function of which is to disperse the product. In general, the pressure and impact forces of the auxiliary explosives contribute to the dislocation of the reservoir, along lines of weakness of this obtained by grooving or by other known means. Fires are obtained either by an impact rocket or by a proximity rocket. In general also in the known devices1 the front part of the projectile comprises an aerodynamic cap whose internal volume is used to accommodate elements of the projectile. It often includes an impact detector. The rear part of the projectile may include propulsion means, for stabilizing the projectile. It also houses elements necessary for the operation of the projectile. The front part, the central part comprising the tank and the rear part can be assembled in different ways. It may be either a single assembled structure, the tank being delimited by a peripheral part of the structure, a front partition and a rear partition. It can also be an assembled structure housing a reservoir having its own structure and fixed inside the assembled structure, forming the structure of the projectile. In general in known devices, the spray of the product, that is to say the volume of distribution of the fragments of product is in the static state distributed approximately omnidirectionally around the body of the projectile. The static state is a state which is encountered practically only during the test phases of the projectile, phases during which the projectile placed on a test base is ignited.

 In the dynamic state, which is the one that is really encountered in operational conditions, the speed of the flakes is the result of two speeds, one is the speed of the tank at the time of dispersion, the other is the speed acquired due to the forces exerted by the dispersing explosive.

Because of this composition of speed, the shape, as a first approximation, spherical of the surface of dispersion in static, has its center which moves at the speed of impact of the projectile and its radius which varies with the speed of dispersion of the fragments from the static state. The approximately spherical surface of dispersion evolves inside a cone envelope of semiangle at the top CL defined by
Sin a = Speed of the flashes of the static display
Sm a =
Velocity of impact of the projectile and top located at the location of the tank at the time of bursting.

In general, the product to be dispersed has ejection speeds limited to the same order of magnitude, or lower, than the speed of the projectile at the time of dispersion, implying, by the law of composition of the speeds, a projection effect towards the before shards.

 However, there are operational situations where this effect is ineffective and where it would be preferable to have a truly omnidirectional projection effect. This situation can occur for example when the projectile entered through an opening in a blockhouse and crashed hard against a wall. Crushing the product against the wall has only a low efficiency and it is preferable to disperse it more omnidirectionally.

 The purpose of the present invention is to make the projectile capable of discriminating between an impact against a solid wall, such as a static wall and a soft wall like those which constitute the walls of light vehicles, therefore to control the dynamic dispersion of the product.

 The first target requires omnidirectional dispersion and the second target requires forward directional dispersion. According to the invention, in the event of a hard impact, the tank is almost immobilized before dispersing, the projected spray then being that of the static state. In the event of a soft shock, the reservoir is almost not slowed down and the spray retains its state of dynamic dispersion characterized by the projection towards the front of all, or almost all, of the mass of incendiary composition.

 According to the invention, this object is achieved, by the particular construction of the cap, by the particular arrangement of the connection mode between the tank and the cap and by a delay in lighting the military head. According to the invention, the cap is deformable so that its length in the axial direction of the projectile decreases in the event of an impact against a hard obstacle, to absorb part, or all, of the energy of the projectile as a function of the dispersion. desired. The cap is deformable so that its length in the axial direction of the projectile decreases in the event of impact against a hard obstacle.

 The reduction in the length of the cap represents the distance of stop or deceleration of the projectile. The order of magnitude of the impact speed is known. The decrease in impact speed is set by the result to be achieved. The decrease in length of the cap directly determines the desired deceleration as well as the value of the delay. The forces of deformation of the cap are calculated to generate a deceleration constantly below the limit that can bear the military load.

 In summary, the invention relates to a projectile having a longitudinal axis XX 'comprising a front cover, at least one military charge structurally linked to the cover, the projectile comprising at least one safety device and firing one of the loads, the projectile being designed to have kinetic energy E on impact, projectile characterized in that the cap is deformable over a length L, under the action of a force F substantially constant during the entire time of the deformation , the force F being calculated to perform over the length L a work at least equal to 90% of the kinetic energy E.

 In the preferred embodiment, the cap is made of a ductile material having good creep qualities, for example dural or brass, and comprises one or more cavities.

It is specified that the energy absorbed by this cap over the length
L is at least equal to 90% of the energy of the projectile in order to clearly distinguish the peculiarity of the cap according to the invention from the other caps. All caps absorb a part of the projectile energy in the event of an impact. By specifying that the cap according to the invention is capable of absorbing at least 90%, over a length L which can be verified by a press test, a distinction is made between the cap according to the invention and an ordinary cap. For a cap absorbing 90% of the kinetic energy of impact on a regular basis, the remaining speed of the part of the projectile located behind the cap is of the order of 3/10 of the initial speed of impact.

 Other characteristics and advantages of the invention will appear during the description which will follow, of an exemplary embodiment of the invention relating to an incendiary projectile, which will be carried out with reference to the attached drawing.

 Figure 1 shows a longitudinal section showing the main elements of the projectile according to the invention and their arrangement.

The projectile 1 comprises, from front to rear, the following elements which will each be described in detail later:
- a cap 10,
a structure 30 comprising a reservoir 40,
- a rear part 50.

The cap 10 has an outer shape ensuring an aerodynamic shape to the projectile. It is made of ductile material and has a transverse through hole 11 to calibrate the deceleration. The perforated part may contain a product intended for secondary military effects or to absorb energy, for example an elastomeric energy-absorbing material for example foam, or a honeycomb structure. This front part is deformable over a length L so that when this cap impacts a hard target with an impact speed Vi representing the speed
Vp of the projectile, the speed of the part behind the cap decreases.

 The structure 30 of the reservoir 40 constitutes an impact-resistant structure on which the deformable structure 10 constituting the cap 10 rests. In the embodiment shown, the cap 10 has a substantially conical shape of revolution around the axis XX 'of the projectile and it has a transverse through hole 11.

The structure 30 comprising the reservoir 40 comprises the following structural elements:
A peripheral structure of revolution 31 around the axis XX 'of the projectile. Rear walls 32 and front 33 define with the peripheral part 31 a sealed enclosure 40 which constitutes the product reservoir.

 The longitudinal and rotational fixing of the structure 31 to the cap 10 is ensured for example by a friction welding process.

 It can be ensured by any means capable of resisting without deformation sensitive to the force transmitted by the cap in the event of a hard impact.

 In the projectile volume defined by the reservoir 40 and coaxial to the latter, is housed a sheath 34 comprising auxiliary explosives 41, an ignition composition 42 necessary for the ejection and ignition of the incendiary product.

 The operation of these explosives in connection with the reservoir 40 and an incendiary product 49 which it contains is in itself known to those skilled in the art.

 A pyrotechnic delay 45 is located in a safety and firing device 52, from a detonating cord 47.

 The rear part 50 is in itself also well known to those skilled in the art. In the case shown of the embodiment of the invention, it comprises deployable fins 51 and intended for the stabilization of the projectile on trajectory. It also houses part of a safety and firing device 52 comprising an impact rocket 53 and producing a signal which lights the ignition cord 47 by means of a delay 45.

The latter can be pyrotechnic or include a part, for example electromechanical capable of providing a delay of great value (from 1 minute to several days). The cord 47 by a sealed passage 46, from the wall 32 initiates the ejection charges 41 which themselves ignite the flash composition 42.

 Before giving relations linking together the value of different parameters to be taken into consideration for dimensioning the elements constituting the invention, the mode of operation of the latter will be briefly recalled.

 On impact, the safety and firing device 52 initiates the cord 47 by means of the delay 45 which is such that the ejection charge 41 is not fired, at the earliest at the end of the deformation of the cap. This ignition is carried out, whether the impact occurs on a hard or soft target.

In both cases, the effect is not the same.

 In this application, on impact on a hard target, the contact force is quite large and allows the cap 10 to be crushed until the structure 31 stops completely or almost completely.

 The dispersion of the fragments resulting from the composition of the tank speeds, and of the projection speeds of the incendiary fragments are then that optimized in static, that is to say omnidirectional.

 On impact on a soft target, the contact force does not allow the cap 10 to be crushed, there is therefore no significant deceleration. There is penetration of the projectile through the target. The dynamic dispersion is in this case directional towards the target.

 Elements relating to the dimensioning of the parameters of the movement of the rear part 40, 50, in the case of impact on a hard target will be given below.

We call:
- Vi, impact speed of the projectile,
- Vr, remaining speed of the rear part of the projectile,
- y supposedly constant deceleration of the rear part during damping,
- T time between the start of impact and the ignition of the dispersion charge, i.e. the minimum delay time 45,
- L, the damping length of the warhead, that is to say the expected length of crushing.

Kinetic energy is absorbed by the length L with a constant deceleration y of the rear part

 The deceleration allows it to size the rear part of the projectile to ensure its resistance to impact on hard target.

 The deceleration law can possibly be adjusted by acting on the structure of the warhead.

The delay time (T) is
2L
5 =
V + Vr
The production of such damping warheads is known to those skilled in the art.

 In the case of use on area decay projectiles with random ignition delay, the time T above is the minimum value of the trigger delay. Vr is 0.

Claims (2)

 1. Projectile having a longitudinal axis XX 'comprising a front cap (10) at least one military charge (30) structurally linked to the cap (10), the projectile comprising at least one safety and firing device (52) d '' one of the charges, the projectile being designed to have kinetic energy E on impact, projectile characterized in that the cap (10) is deformable over a length L, under the action of a substantially constant force F during all the time of the deformation, the force F being calculated to perform on the length L a work at least equal to 90% of the kinetic energy E.  2. Projectile according to claim 1, characterized in that the firing of a military charge is carried out by means of a delay (45) at least equal to the crushing time (X) of the cap (10 ).