FR2771807A1 - DEVICE FOR PROGRAMMING A PROJECTILE INSIDE A WEAPON TUBE - Google Patents

Abstract

The technical sector of the invention is that of ammunition, in particular of large caliber. The invention relates to a device for programming a projectile (4) inside a weapon tube (2) comprising a receiver (6) integral with the projectile, characterized in that it comprises a reflector (11) integral with the barrel of the weapon and positioned in the immediate vicinity of the muzzle of the barrel of the weapon, the reflector receiving waves (15 ) sent by a transmitter (5) arranged outside the barrel of the weapon and reflecting them towards the interior of the barrel of the weapon.

Description

The technical field of the invention is that of

  programming of projectiles, in particular for field artillery ammunition or large caliber tanks.5 Current projectiles are more and more often

  equipped with multi-mode, impact, proximity, chronometric rockets, which are adapted to different targets.

  For this type of projectile it appears necessary, even essential, in order to increase the probability of lethal damage to the target, to be able to transmit data relating to their potential target to them. These data can be the nature and the coordinates of the target, the trajectory, but also meteorological information ... Large caliber ammunition, called "intelligent", equipped with infrared sensors for their terminal guidance, as well as ammunition equipped with a GPS, can also

  benefit from the transmission of such data. The programming of a projectile on a trajectory is known in the state of the art.

  For example, patent FR2608267 describes a device allowing the programming of a projectile by optical means.

  This device requires optical emission means and means for monitoring the projectile until the programming phase. The projectile must also have at its rear part means for receiving the light signals. Projectile tracking is restrictive, because until programming the weapon system is inoperative and very good intervisibility without obstacle between the projectile and the tracking means is necessary.30 In order to avoid these constraints, programming the projectile can be carried out when it is inside the barrel of the weapon, either when it is still stationed, or during its ballistic phase inside the barrel. Thus patent EP0023365 proposes a device for measuring the speed and / or programming of a projectile inside a weapon tube. For this, the device provides for the installation of an antenna in a bore made in the wall of the barrel of the weapon or in the orifices of the muzzle brake. The antenna, which is connected to a source

  of energy, sends microwave radiation inside the barrel of the weapon. These microwave radiations make it possible to measure the initial speed of the projectile and / or to program it.

  This device poses many problems.

  First of all the machining of a bore in the barrel of a weapon is hardly favorable to its mechanical behavior and risk of

  disrupt the interior and then exterior ballistics of the projectile.

  In addition, the technical implementation of this device is difficult and requires many additional parts.

  Then, successive shots generate shock waves, vibrations, temperatures and very high pressures at the muzzle of the barrel. The antenna located near the mouth of the tube is therefore subject to these constraints and disturbances which can cause technical problems. Finally, the antenna being placed perpendicular to the axis of the barrel of the weapon, the radiation from the energy source is scattered in all directions. Indeed, with this device the programming of the projectile is possible both when it is in the barrel of the weapon and after its exit, therefore on trajectory. Only a small part of the radiation is therefore directed towards the inside of the tube in the direction of the ammunition, which generates an unfavorable energy balance, therefore a poor reliability of programming in the tube. It is the object of the invention to propose a device for programming a projectile in the barrel of a weapon, a device which is simple, inexpensive, insensitive to the constraints of shooting, of high reliability and requiring no no machining at the core of the barrel of the weapon. Thus the subject of the invention is a device for programming a projectile inside a weapon tube comprising a receiver secured to the projectile which is characterized in that it comprises a reflector secured to the barrel of the weapon and positioned in the immediate vicinity of the

  muzzle of the weapon barrel, the reflector receiving waves sent by a transmitter placed outside the barrel of the weapon and reflecting them towards the interior of the barrel of the weapon.

  According to a first embodiment, the reflector is a mirror.

  According to a second embodiment, the reflector is a reflecting surface integral with a blade of a brake

mouth.

  The programming device according to the invention comprises a transmission line between the transmitter and the reflector which can be a coaxial line or a waveguide. Preferably, the frequency of the waves

  electromagnetic emission is greater than or equal to 2.5 GHz.

  The invention will be better understood on reading the description of particular embodiments, made in

  reference to the accompanying drawings in which: - Figure 1 shows a partial schematic section

  of a weapon tube according to a first embodiment of the invention.

  - Figure 2 shows, in section, the front end of a weapon tube fitted with a muzzle brake according to a second embodiment of the invention.25 - Figure 3 schematically shows in half-section a blade of a muzzle brake according to an alternative embodiment of the invention. Referring to Figure 1, a weapon 1, for example of large caliber, is conventionally composed of a tube 2

  mounted on a cylinder head 3. A munition 4 is stationed inside the tube 2, ready to be fired.

  According to the invention, the weapon 1 is equipped with a device for programming the ammunition 4 composed of a transmitter

  electromagnetic waves 5 of the microwave type and a wave receiver 6.

  The wave emitter 5 comprises a wave generator 7 and a transmission line 9. The wave generator 7 is positioned on the outside of the tube 2, so that the transmission line 9 opens substantially close of

  the front end 10 of the tube 2. The transmission line 9 is here a coaxial line which is preferably provided with an antenna 8 at its front end in order to optimize the directivity of the waves emitted.

  The wave receiver 6 is an antenna housed at the level of a rocket 14 of the munition 4. An electronics for processing the received waves is also integrated in the munition 4.10 A metal reflector 11 is mounted at the end of the tube 2, for example by screwing on the outside of the tube. It has a planar reflecting surface 12 inclined relative to the axis XX 'of the weapon 1 at an angle a less than 90 C, for example of the order of 60 C. The reflector 11 has at least one opening radial 13 positioned in the vicinity of the reflecting surface 12. The angle a is chosen so that an incident ray on the reflecting surface is reflected towards the inside of the barrel of the weapon. 20 The operation of the programming device according to the invention is as follows: - the wave generator 7 emits radiation 15 which is conducted by the transmission line 9 towards the reflector 11.25 - the radiation 15 impacts the reflecting surface 12 of the reflector 11 then, due to the inclination of the reflecting surface is reflected towards the inside of the barrel 2 of the weapon. - finally, the tube 2 acts as a waveguide and

  transports the radiation 15 towards the receiving antenna 6 of the munition 4.

  The radiation 15, transported to the receiver 6 of the ammunition 4, thus makes it possible to transmit data and / or

  program the ammunition before the latter is actually fired, while it is still stationed inside the barrel of the weapon.

  Programming or data transmission can also be carried out during the entire trajectory of the projectile

  down the barrel to the mouth.

  The device for programming a projectile according to the invention therefore does not require any machining which weakens the wall of the barrel of the weapon. The directed reflection of the radiation by the reflecting surface 12 towards the interior of the barrel of the weapon makes it possible to '' improve the energy balance penetrating inside the barrel of the weapon. Elements sensitive to firing constraints, such as the wave generator, are distant from the muzzle of the tube and could, as a variant, be placed outside of the muzzle, as on the vehicle turret, by having a transmission line. slightly longer. Alternatively, the reflector 11 could be a mirror

  fixed in front of the barrel and oriented so as to direct the radiation inside the barrel of the weapon.

  According to another variant, the coaxial line can be replaced by a waveguide which would assume the role of transmission line. This waveguide would also be positioned on the outside of the tube and its front end would be open. The waveguide has several advantages: on the one hand the energy losses during transmission are less than with a coaxial line, and on the other hand its rusticity gives it better mechanical protection against external aggressions. At the end of the waveguide, on the side of the reflector, it is possible to add a horn antenna intended to improve the directivity of the radiation. Figure 2 shows the end of a weapon tube according to

  a second embodiment of the invention.

  The tube 2 has at its front end a muzzle brake 16 made integral with the tube by means of a thread 17. A nut 20 ensures the locking of the tube / muzzle brake assembly. 35 The muzzle brake 16 comprises two groups of openings or gills 18a and 18b, here six in number per group. The openings 18a, 18b are respectively extended by vanes 19a, 19b which each have a flat surface 21 and a concave surface 22 whose concavity is oriented towards the rear of the weapon. The concavity of the blades 19a, 19b is adopted, in known manner, to compensate for the force exerted by the combustion gases. 5 The wave emitter 5 and the receiver 6 described in the first embodiment represented in FIG. 1 are

  included in this second embodiment but are not shown. Advantageously, the front end of the transmission line 9 will be placed near an opening 18a10 of the muzzle brake 16.

  The radiation 15, coming from the emitter 5, impacts the blade 19a which here acts as a reflecting surface, then is reflected and penetrates inside the core of the tube 2 by passing through one of the openings 18a. The concavity 22 of the blade 19a of the muzzle brake is defined so as to ensure the directivity of the radiation towards the interior of the tube.

  tear. The tube 2, which then serves as a waveguide, transmits the radiation 15 to the receiving antenna of the ammunition 4, thus allowing the programming of the latter.

  In this embodiment, the muzzle brake 16 is advantageously used as a reflector and the concave surface 22 of the blade 19a as a reflecting surface. The angle of inclination or the radius of curvature of the reflecting surface will be easily determined by a person skilled in the art as a function of the internal diameter of the barrel 2 of the weapon, of the distance from the reflecting surface to the front end 10 of the tube, as well as of the place of reflection of the radiation on the reflecting surface. Those skilled in the art will also easily define the usable frequency bands. These depend on the internal diameter of the tube, the dimensions of the muzzle brake opening, the surface and the shape of the reflecting surface, as well as the type of receiving antenna and the type of transmission lines. The most restrictive criterion is the size of the muzzle brake opening. Thus, to allow the minimum attenuation of the signal during the passage of the wave from the outside towards the inside of the tube through the opening 18a of the muzzle brake, a wavelength d will be chosen. 'emission less than or equal to twice the largest dimension of the opening. Thus, with reference to Figure 3, a muzzle brake 16, shown partially and schematically, is secured to the front end of a tube 2 of a weapon. The tube 2 is here a smooth tube with an internal diameter D equal to 140 min. The muzzle brake 16 has at least one opening 18a of length L and width 1. It also has, in front of the opening 18a, at least one blade 19 intended to compensate for the force exerted by the combustion gases. The blade 19 has an inclined surface 23, of length h in projection on a plane perpendicular to the axis XX ', forming a truncated cone and a concave surface 22. The frustoconical surface 23, which receives a wave 15 emitted by a wave emitter not shown and which will be described later, has a half-angle at the top a substantially equal to 60 C. The angle a is the average of two angles a1 and a2. For a wave 15 emitted at a fixed distance from the wall of the tube 2 (for example at a distance h / 2) the angle al corresponds to the minimum angle of inclination of the reflecting surface 23 allowing the reflected wave 24 to penetrate into the core of the tube, without leaving through the openings 25 18a and the angle a2 corresponds to the maximum angle allowing the reflected wave 25 to penetrate into the core of the tube, without

  interfere with the front 10 of the tube. Thus the wave 15 reflected by the surface 23, which is inclined at an angle a, penetrates inside the barrel of the weapon without interference in a direction 26, then propagates in the latter until the munition.

  The opening 18a of the muzzle brake has a length L equal to 60 mm which allows the reflected wave to penetrate

  inside the tube core without interference. The opening 35 is positioned between the blade 19 and the front 10 of the tube 2. Its width 1 is 30 mm.

  To allow the minimum signal attenuation during the passage of the wave from the outside to the inside of the tube through the opening 18a of the muzzle brake, a lower emission wavelength or equal to twice the largest dimension of the opening, here the length L of 60 mm. Indeed, according to the Babinet principle (5-slot antenna), radiation through an opening of length L is total when L> -, X being the wavelength of C radiation. Thus, knowing that A = -, C being the speed F and F the frequency, the minimum frequency of use allowing a rate of penetration of the signal inside the c tube which is satisfactory, will be greater than, either

  2L greater than or equal to 2.5 GHz.

  The means for transmitting and receiving waves will be easily defined by a person skilled in the art.

  For the embodiment defined above, the wave emitter will preferably be composed of an electromagnetic wave generator, which can emit under

  a frequency substantially equal to 10 GHz, of the klystron or magnetron type and of a transmission line which could be a waveguide filled with air.20 The wave receiver housed inside the projectile could be an antenna thin patch type.

  Of course, without departing from the scope of the invention, the device can be used for weapons of any caliber,

  in particular for the programming of ammunition of medium25 caliber, even of small caliber.

Claims (4)

CLAIMS l - Device for programming a projectile (4) inside a weapon tube (2) comprising a receiver (6) secured to the projectile, characterized in that it comprises a reflector (11) secured of the barrel of the weapon and positioned in the immediate vicinity of the muzzle of the barrel of the weapon, the reflector receiving waves (15) sent by a transmitter (5) disposed outside the barrel of the weapon and reflecting them inward of the barrel of the weapon.   2 - Programming device according to claim 1, characterized in that the reflector (11) is a mirror.   3 - Programming device according to claim 1, characterized in that the reflector (11) is a reflecting surface integral with a blade (19) of a muzzle brake (16).   4 - Programming device according to any one of claims 1 to 3, characterized in that it comprises   a transmission line (9) between the transmitter (5) and the reflector (11).   - Programming device according to claim 4, characterized in that the transmission line (9) is a coaxial line. 6 - Programming device according to claim 4,   characterized in that the transmission line (9) is a waveguide.   7 - Programming device according to any one of claims 1 to 6, characterized in that the frequency   electromagnetic waves emitted is greater than or equal to 2.5 GHz.