RU2622177C1 - Method of object protection from destruction means with optoelectronic and radar guidance targeting and detonation systems - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: method of object protection from a destruction means with optoelectronic and radar targeting and detonation systems involves determining the trajectory of the destruction means, delivering the object's protection equipment to the calculated point of the attacking destruction means trajectory, and bringing the object's protection equipment into perant condition. The object is protected by a plasma-vortex formation formed when the protective equipment is detonated in the form of a body with a hollow cylindrical charge of a blasting explosive and an aluminium tube in the cavity of a cylindrical charge by way of a plasma-forming substance.

EFFECT: increased reliability of object protection.

1 dwg

Description

FIELD OF THE INVENTION

The invention relates to the field of electronic warfare and can be used to protect objects from weapons with optical-electronic and radar guidance and detonation systems. As a means of destruction, missiles, shells, air bombs, cluster munitions related to high-precision weapons (hereinafter referred to as the attacking element of high-precision weapons (AE WTO)) are considered.

State of the art

A known method of protecting an object, implemented, for example, when the device is used to protect objects (patent RU No. 2403586, G01S 7/38, 2008) and providing for the determination of the trajectory of the weapon, the delivery of the protective equipment to the target point of the trajectory of the attacking weapon and bringing the tool protect the facility in working condition. The known method is used in the radio frequency range of electromagnetic waves.

The disadvantage of this method is the low reliability.

The closest in technical essence to the proposed one is a method of protecting an object from means of destruction, which includes determining the trajectory of the means of destruction, delivering the means of protection of the object to the calculated point of the trajectory of the attacking means of destruction and bringing the means of protection of the object into working condition (patent RU No. 2502082, G01 7/38 , 2011).

According to the known method, an aerosol cloud is created on the trajectory of the attacking weapon, reflecting the radiation (optical, infrared or radio emission) of a non-contact remote fuse of the weapon and causing it to prematurely trigger and subsequent premature detonation of the warhead, which does not harm the protected object.

The disadvantage of this method is the low reliability of the protection of the object due to the low probability of premature operation of a non-contact remote fuse of a weapon, leading to the undermining of the warhead and the self-destruction of the weapon.

This drawback is due to the fact that when radiation interacts with an aerosol cloud, which is a dispersed physical medium, the incident radiation is scattered in different directions, while a small part of the energy radiated in the opposite direction (i.e., towards the attacking means of destruction) non-contact remote fuse of the attacking weapon. For this reason, the signal level at the receiver of a non-contact remote fuse is small and, therefore, the probability of its operation is small.

Disclosure of invention

The objective of the present invention is to provide protection of objects from shells, missiles, bombs, cluster munitions and other types of precision weapons with radar and optoelectronic guidance and detonation systems.

The technical result from the application of the proposed method is to increase the reliability of protecting the object from attacking elements of the WTO with optoelectronic and radar guidance and detonation systems by increasing the level of the reflected signal and increasing the likelihood of a non-contact remote fuse of a weapon, as well as expanding the scope of the method.

The specified technical result is achieved by the fact that in the method of protecting an object from weapons with optoelectronic and radar guidance and detonation systems, which includes determining the path of the weapon, delivering the object’s defense (ammunition of plasma-optical action (AML)) to the target point of the attacker's path the WTO element and bringing the facility’s protective equipment into working condition, the facility’s protection is carried out with the help of a plasma-vortex formation formed by undermining the LHB de hollow cylindrical body with a charge of high explosive and aluminum tube in a cavity of a cylindrical charge as the plasma substance.

The implementation of the invention

To implement the proposed method requires the following technical means:

1) A reconnaissance station that provides detection of an attacking weapon, determination of its coordinates and trajectory.

2) A microprocessor-based computing unit that processes data from the reconnaissance station in real time and issues target designation instructions.

3) A means of delivering an AML to the calculated point of the trajectory of the attacking element of high-precision weapons.

Such means may be, for example, artillery shells of various calibers fired from a cannon, including quick-firing cannons, or missiles (uncontrolled or guided) launched by appropriate launchers.

The rate of fire of a modern 30 mm automatic gun is 6000 rds / min (respectively, a firing frequency of 100 Hz), the speed of a 30 mm projectile upon exiting the barrel is ν ₀ ≈ 500 ... 1000 m / s, i.e. the shells follow each other at a distance of 5 ... 10 m. The gun has a device for transmitting the fuse response time to the projectile inside the barrel by the inductive method. The gun is equipped with program-controlled drives that provide barrel movement in azimuth and elevation angle at a given speed.

4) A protective device in the form of a body with a hollow cylindrical charge of a blasting explosive and an aluminum tube in the cavity of a cylindrical charge as a plasma-forming substance (such ammunition can be made, for example, on the basis of an explosive plasma-vortex radiation source described in the Journal of Technical Physics " , 2010, Volume 80, No. 11, pp. 87-94).

The implementation of the proposed method will be clear from the example described below and shown in the drawing.

Reconnaissance station 1 detects and tracks the movement of the attacking element of the WTO 2 towards the protected object 3. The angular coordinates of the AE of the WTO 2, the direction and speed of its movement, the current distance to it are continuously supplied to the computing unit 4. These data are processed by the computing unit 4 taking into account the coordinates of the place positioning launcher 5 means of delivery means of protection of the object. The results of calculations in the form of target designation commands in azimuth and elevation angle, in terms of blasting time and angular velocity of rotation of the barrel are delivered to the launcher drives (rapid-fire artillery mount) 5. At the estimated time, the launch (shot, series of shots) is carried out and the protective equipment is delivered to the calculated point of the trajectory of the attacking element of the WTO 2, in which the cylindrical charge of the explosive is detonated.

As a result of undermining the protective equipment on the trajectory in front of the attacking element of high-precision weapons 2, a long-lived plasma-vortex formation 6 is formed (several such formations when firing a burst) in the form of a spheroid with a characteristic diameter of the order of several meters (depending on the mass of the explosive charge). In the fast phase of the LARP response process - the phase of shock braking of a high-speed jet in air - more than 50% of the radiated energy falls on the ultraviolet region of the spectrum, whose short-wavelength quanta cause photoionization of the surrounding air. In the process of further deceleration of the jet in the air (slow phase), a plasma toroidal vortex is formed with characteristic plasma temperatures of 3000 ... 5000 K. The lifetime of a plasma vortex in the air is tens and hundreds of milliseconds (up to 0.1 s). During this time, a sufficiently high electron concentration — 10 ¹² ... 10 ¹⁴ cm ³ — remains in the plasma vortex.

The non-contact remote munition fuse 2 sends a probe signal in the direction of the target, the signal hits the plasma-vortex formation 6, is reflected from it and causes the fuse to fire and eliminate the munition 2 at a safe distance for the protected object 3.

The reflective properties of the plasma-vortex formation 6 due to the presence of aluminum dioxide in the droplet phase significantly exceed the similar characteristics of the aerosol cloud of the prototype, since the physical phenomenon of reflection of radiation in the direction of the attacking munition 2 is much more effective than scattering in an aerosol dispersed medium. As a result, the level of the reflected signal arriving at the receiver of the remote proximity fuse significantly increases with respect to the prototype and, thereby, increases the likelihood of premature detonation of ammunition 2, i.e. improving the reliability of protection of the object 3.

These advantages of the proposed method are realized for a wide range of weapons with non-contact remote fuses operating in the radio and optical wavelength ranges.

In addition, the technical result from the application of the proposed method is also due to the fact that the impact of the protective equipment in the form of a plasma-vortex formation 6 on the means of destruction is carried out not only with respect to the non-contact remote fuse, but also with respect to the homing head (GOS) of the AE of the WTO. This effect is due to the fact that when a hollow cylindrical charge of a blasting explosive and an aluminum tube is detonated due to the shock braking of a plasma jet in atmospheric air, a powerful high-energy pulse of broadband electromagnetic radiation of the optical spectrum range (0.19 ... 14 μm) is generated. The brightness of such radiation is many times higher than the brightness of solar radiation and corresponds to radiation temperatures of 15,000 ... 20,000 K, the front of increasing radiation intensity falls on the microsecond duration range.

The impact on the seeker consists, firstly, in a powerful radiation pulse (flash) during the detonation of LARP in atmospheric air (optical-electronic seekers of all existing and prospective spectral ranges of operation) and, secondly, in the screening effect of a long-lived plasma-vortex formation 6 (GOS radio and optical ranges), which leads to the loss of the target of the GOS means of destruction.

Thus, when implementing the proposed method, there is a multi-channel effect on the guidance and detonation systems of the means of destruction, which leads to an increase in the reliability of protection of objects and the expansion of the scope of the method.

The expansion of the possibilities for the application of the proposed method lies in the fact that the method can be used to protect objects from weapons, not equipped with a non-contact remote fuse. In this case, the impact is carried out only on the homing head.

Claims (1)

A method of protecting an object from means of destruction with optical-electronic and radar guidance and detonation systems, which includes determining the path of the weapon, delivering the means of protection of the object to the calculated point of the trajectory of the attacking means of destruction and bringing the means of protection of the object into working condition, characterized in that the object is protected with the help of a plasma-vortex formation formed by detonating a protective device in the form of a body with a hollow cylindrical charge of a blasting explosive eschestva aluminum tube and the cylindrical cavity in charge as the plasma substance.

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