DE69811187T2 - Device for programming a projectile inside a gun barrel - Google Patents

Description

The technical field of the invention relates to devices for programming projectiles, in particular for ammunition for land artillery or large caliber tanks.

Current projectiles are increasingly equipped with multi-function fuses, impact, proximity, time, adapted to the different targets. For this type of projectile, it seems necessary, even essential, to transmit data on their possible targets in order to increase the chances of hitting the target lethally. This data may be the type and coordinates of the target, the trajectory, but also meteorological information.

Large caliber ammunition, so-called "intelligent" ammunition, which is equipped with infrared sensors for its fire control system, as well as ammunition equipped with GPS, can also benefit from the transmission of such data.

Programming a projectile on its trajectory is well known in the art.

For example, patent FR2608267 discloses a device that allows the programming of a projectile by optical means. This device requires optical emission means and means for tracking the projectile until the programming phase. The projectile must also have a means for receiving light signals at its rear. Tracking the projectile is limiting because the weapon system is ineffective until programming and a very good line of sight without any obstacles between the projectile and the tracking means is necessary.

To avoid these limitations, the programming of the projectile can be done when it is inside the gun barrel, either when it is still in position or during its ballistic phase inside the barrel.

For example, patent EP0023365 proposes a device for measuring the speed and/or programming a projectile inside a gun barrel. To this end, the device provides for the installation of an antenna in a hole in the wall of the gun barrel or in the openings of the Muzzle brake. The antenna, which is connected to a power source, emits microwave radiation into the interior of the weapon barrel. This microwave radiation allows the initial velocity of the projectile to be measured and/or programmed.

This device presents numerous problems.

First of all, the use of an opening in the gun barrel is hardly beneficial for its mechanical behavior and runs the risk of disturbing the internal and then external ballistics of the projectile.

In addition, the technical application of this device is difficult and requires numerous additional parts.

The successive shots then generate shock waves, vibrations and very high temperatures and pressures in the area of the gun's muzzle. The antenna located near the muzzle is therefore subject to these stresses and disturbances, which can cause technical problems.

Finally, the emissions from the energy source are scattered in all directions, since the antenna is positioned perpendicular to the axis of the barrel. This device certainly makes it possible to program the projectile when it is in the barrel, as well as after it has exited, i.e. during its flight. Only a small proportion of the emissions are therefore directed into the barrel towards the ammunition, which results in an unfavourable energy balance and therefore poor reliability of the programming in the barrel.

The object of the invention is to propose a device for programming a projectile in the barrel of a weapon, whereby the device should be simple, inexpensive, insensitive to the stresses of firing and have a high level of reliability and do not require any processing in the area of the weapon barrel core.

Thus, the subject of the invention is a device for programming a projectile inside a gun barrel with a receiver firmly connected to the projectile, which is characterized in that it comprises a reflector which is firmly connected to the gun barrel and in the immediate vicinity of the is arranged near the mouth of the weapon barrel, whereby the reflector receives the waves emitted by a transmitter arranged outside the weapon barrel and reflects them into the interior of the weapon barrel.

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

According to a second embodiment, the reflector is a reflective surface firmly connected to a wing of a muzzle brake.

The programming device according to the invention comprises a transmission line between the transmitter and the reflector, which may be a coaxial line or a waveguide.

Preferably, the frequency of the emitted electromagnetic waves is greater than or equal to 2.5 GHz.

The invention will be more clearly understood from the description of specific embodiments, which refer to the accompanying drawings, in which:

- Fig. 1 shows a schematic partial section of a gun barrel according to a first embodiment of the invention.

- Fig. 2 shows the front end of a weapon barrel in section which is equipped with a muzzle brake according to a second embodiment of the invention.

- Fig. 3 shows schematically in half section a wing of the muzzle brake according to an embodiment variant.

Referring to Fig. 1, a weapon 1, for example of large caliber, consists in a classic manner of a barrel 2 mounted on a gun breech 3. An ammunition 4 is located inside the barrel 2, ready to be fired.

According to the invention, the weapon 1 is equipped with a device for programming the ammunition 4, which consists of a transmitter of electromagnetic waves 5, in the form of microwaves, and a wave receiver 6.

The transmitter of waves 5 comprises a wave generator 7 and a transmission line 9. The wave generator 7 is located on the outside of the pipe 2, such that the transmission line 9 extends clearly up to the vicinity 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 emitted waves.

The wave receiver 6 is an antenna arranged in the area of a projectile head 14 of the ammunition 4. Electronics for processing the received waves are also contained in the ammunition 4.

A metal reflector 11 is fixed to the end of the tube 2, for example by screwing it onto the outside of the tube. It comprises a reflecting surface 12 which is flat and inclined with respect to the axis XX' of the weapon 1 by an angle α less than 90º, for example of the order of 60º. The reflector 11 has at least one radial opening 13 located near the reflecting surface 12. The angle α is chosen such that a beam incident on the reflecting surface is reflected into the interior of the weapon barrel.

The operation of the programming device according to the invention is as follows:

- The wave generator 7 emits radiation 15, which is guided via the transmission line 9 towards the reflector 11.

- The radiation 15 strikes the reflecting surface 12 of the reflector 11 and is then reflected towards the interior of the weapon barrel 2 due to the inclination of the reflecting surface.

- Finally, the tube 2 plays a role as a waveguide and transports the radiation 15 towards the receiving antenna 6 of the ammunition 4.

The radiation 15 transported to the receiver 6 of the ammunition 4 allows data to be transmitted and/or the ammunition to be programmed before it is actually fired, while it is still in position inside the weapon barrel.

Programming or data transmission can also take place along the entire path of the projectile in the gun barrel up to the muzzle.

The device for programming a projectile according to the invention therefore does not require any machining that would embrittle the wall of the weapon barrel.

The reflection of the radiation directed by the reflecting surface 12 into the interior of the weapon barrel makes it possible to improve the balance of the energy penetrating into the interior of the weapon barrel.

The parts sensitive to the shot loads, such as the wave generator, are moved away from the muzzle and could, as a variant, be arranged outside the gun barrel, as on the vehicle body, by providing a slightly longer transmission line.

As a variant, the reflector 11 could be a mirror mounted in front of the barrel, which is oriented in such a way that it directs the radiation into the interior of the weapon barrel.

According to another variant, the coaxial cable can be replaced by a waveguide, which would ensure the role of the transmission line. This waveguide would also be located 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 lower than with a coaxial cable and on the other hand, its robustness gives it better mechanical protection against external influences. At the end of the waveguide, on the reflector side, a horn antenna can be added to improve the directivity of the radiation.

Fig. 2 shows the end of a weapon barrel according to a second embodiment of the invention.

The tube 2 comprises a muzzle brake 16 at its front end, which is firmly connected to the tube by a thread 17. A castle nut 20 ensures the locking of the tube/muzzle brake unit.

The muzzle brake 16 comprises two groups of openings or air inlets 18a and 18b, here the number is six per group. The openings 18a, 18b are extended by wings 19a, 19b, which have a flat surface 21 and a concave surface 22, the concavity of which towards the rear part of the weapon. The concavity of the wings 19a, 19b has been accommodated in a known manner in order to compensate for the stresses exerted by the combustion gases.

The wave transmitters 5 and receivers 6 described in the first embodiment represented by Fig. 1 are repeated in this second embodiment, but are not shown. Advantageously, the front end of the transmission line 9 is arranged near the opening 18a of the muzzle brake 16.

The radiation 15 emitted by the transmitter 5 strikes the wing 19a, which here plays the role of the reflecting surface, is then reflected and penetrates into the interior of the core of the barrel 2 by passing through one of the openings 18a. The concavity 22 of the wing 19a of the muzzle brake is set in such a way as to ensure the directivity of the radiation into the interior of the weapon barrel. The tube 2, which now serves as a waveguide, transmits the radiation to the receiving antenna of the ammunition 4, thus enabling it to be programmed.

In this embodiment, the muzzle brake 16 is advantageously used as a reflector and the concave surface of the wing 1% as a reflecting surface.

The expert can easily determine the angle of inclination or the radius of curvature of the reflecting surface as a function of the inner diameter of the weapon barrel 2, the distance of the reflecting surface from the front end 10 of the barrel and the location of the reflection of the radiation on the reflecting surface.

The expert will also easily define the frequency bands that can be used. These depend on the inner diameter of the tube, the dimensions of the muzzle brake openings, the surface and shape of the reflecting surface, as well as the type of receiving antenna and transmission lines. The most limiting criterion is the size of the muzzle brake opening. For example, in order to allow a minimum of signal attenuation when the waves pass from the outer to the inner region of the tube through the muzzle brake opening 18a, choose a length of the emitted waves that is less than or equal to twice the largest dimension of the opening.

Thus, with reference to Fig. 3, a muzzle brake 16, which is partially shown schematically, is designed as one piece with the front end of the weapon barrel 2. The barrel 2 is here a smooth tube with an inner diameter D of 140 mm.

The muzzle brake 16 has at least one opening 18a of length L and width 1. It also has at least one wing 19 in the front area of the opening 18a, which is designed to compensate for the loads exerted by the combustion gases.

The wing 19 comprises an inclined surface 23 of length h in projection perpendicular to the axis XX' and forms a truncated cone and a concave surface 22. The frustoconical surface 23, which receives a wave 15 emitted by the wave transmitter (not shown) and which will be described later, has a semiconical angle α of approximately 60º. The angle α is the average of two angles α1 and a2. For a wave 15 emitted at a fixed distance from the barrel wall 2 (for example h/2), the angle α1 corresponds to the minimum angle of inclination of the reflecting surface 23 which allows the reflected wave 24 to penetrate into the core of the barrel without exiting from the openings 18a, and the angle α2 corresponds to the maximum angle which allows the reflected wave 25 to penetrate into the core of the barrel without interfering with the front edge 10 of the barrel. Thus, the wave 15 reflected by the surface 23 inclined by an angle α penetrates without interference along a direction 26 into the interior of the weapon barrel and then propagates to the ammunition.

The opening 18a of the muzzle brake has a length L of 60 mm, which allows the reflected wave to penetrate into the core of the tube without interference. The opening is arranged between the wing 19 and the front edge 10 of the tube 2. Its width is 30 mm.

In order to achieve a minimum of signal attenuation when the waves pass from the outer to the inner area of the barrel through the opening 18a of the muzzle brake, a length of radiated waves that is less than or equal to twice the largest dimension of the opening, the length L here being 60 mm. According to Babinet's principle (slotted antenna), radiation through an opening of length L is complete if L > λ/2 where λ is the wavelength of the radiation. For example, knowing that λ = C/F where C is the propagation speed and F is the frequency, the minimum frequency of use that allows a satisfactory signal penetration rate inside the tube is greater than C/2L, can be greater than or equal to 2.5 GHz.

The means of transmitting and receiving the waves will be easily determined by the expert.

As an example of the embodiment defined above, the wave transmitter preferably consists of an electromagnetic wave generator of the klystron or magnetron type capable of radiating at a frequency of approximately 10 GHz and a transmission line which may be an air-filled waveguide.

The wave receiver located inside the projectile can be a small "patch" type antenna.

Of course, without departing from the scope of the invention, the device can be used for weapons of all calibers, in particular for programming medium caliber, even small caliber, ammunition.

Claims (7)

1. Device for programming a projectile (4) inside a weapon barrel (2) with a receiver (6) firmly connected to the projectile, characterized in that it comprises a reflector (11) which is firmly connected to the weapon barrel and arranged in the immediate vicinity of the mouth of the weapon barrel, the reflector receiving the waves (15) emitted by a transmitter (5) arranged outside the weapon barrel and reflecting them into the interior of the weapon barrel. 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 reflective surface firmly connected to a wing (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). 5. 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 of the radiated electromagnetic waves is higher than or equal to 2.5 GHz.