RU2679377C1 - Method of countering the implementation of tasks to the unlimited aircraft - Google Patents

Abstract

FIELD: aviation.SUBSTANCE: method is implemented using one or a group of network carriers on which the network is fixed with the possibility of folding, deployment and separation, oriented vertically relative to the surface of the earth. Additional network is fixed on the carrier, designed to apprehend bombs dropped by unmanned aerial vehicles or to counter other hazards emanating from it and made with the ability to take when turning horizontal or close to the horizontal position relative to the surface of the earth, at the same time, the networks are attached to carriers with the possibility of discharge when capturing flying objects.EFFECT: provides increased protection of objects from the attack of unmanned aerial vehicles and their means of destruction.8 cl

Description

The invention relates to methods for preventing the penetration of enemy reconnaissance and attack facilities using wire or wire fences made of other material and can be used in peacetime to prevent terrorist penetrations of unmanned aerial vehicles into a controlled territory for the purpose of reconnaissance or terrorist attack, and when conducting combat operations when the enemy conducts reconnaissance flights and strikes at targets using unmanned aerial vehicles x aircraft (UAV).

Unmanned aerial vehicles have been known for quite some time, including as a tool for terrorists. However, at present, the level of terrorist use of ultra-small unmanned autonomous (or remotely controlled) aircraft (drones) has risen dramatically (for example, we can recall the attacks on our bases in Syria) so that it becomes absolutely clear to everyone that these devices will sooner or later they were also used against the concentration of civilians in cities that, unlike military bases, have neither radar, nor warning equipment, nor countermeasures to such threats. Also, opposition is greatly hampered by urban development conditions and a very short flight time. In addition, the civilian population is not specially prepared for military operations and in the event of an attack, panic is possible, leading to even greater casualties.

The current means of dealing with such a threat in cities (drones - fighter drones, special electronic guns for intercepting drones, as well as hand grenade launchers for their capture) are not yet available in sufficient quantities, their use has not been worked out and they are able to deal with a threat only pointwise, in a small amount, from a short distance and one at a time (and militants use, as practice has shown, entire squadrons). Also in the city it is impossible to use powerful electromagnetic pulses that would destroy the drone control system because such a tool would destroy the city’s electronic systems (for example, cellular communications), which is unacceptable. Well, traditional military means such as aviation, anti-aircraft guns and rocket launchers, even with special missiles, are also impossible to use in cities.

There is a known (http://vpvo.narod.ru/Weapon/ZrkyTunguskam/tunguskam.html) method for counteracting the performance of tasks by an unmanned aerial vehicle, carried out by an anti-aircraft complex and consisting in a radar survey of airspace, in detecting UAVs using a radar detection station, in capture UAVs for automatic tracking along the elevation angle s and azimuth P, and possibly along the range R by the target tracking station, in choosing the UAV complex shooting mode (cannon or missile weapons), in transmitting UAV coordinates and other data from the station and detection and escort stations to the central computing system to solve the firing control problem in accordance with the selected firing mode, in firing at UAVs and in hitting them with fragments of the warhead of a rocket or shells, in evaluating the results of firing to determine the need for re-firing of the UAV or transferring fire to another target.

The disadvantage of this method is the low probability of UAV detection by the complex detection station, especially when using mini-UAVs and micro-UAVs with geometric dimensions of less than one meter; significantly reduced (compared with other typical air defense systems for anti-aircraft systems) probability of damage even in the depth of the affected area at short range, since this probability significantly depends on the geometric dimensions of the target; the relative high cost of implementation, since the cost of combat equipment of the anti-aircraft complex significantly exceeds the cost of UAVs, the tasks of which can be duplicated by several other UAVs of the same type, and after taking the UAVs for escort, the complex reveals its location and can become the object of impact of other UAVs, anti-radar missiles, guided by air bombs, etc. .

Also known (SU, copyright certificate 63785, publ. 06/30/1944) aerostat boom, connected to the ground by means of a cable and designed to detain aircraft.

A disadvantage of the known device should be recognized as its low efficiency, due to the small overlapping area of airspace.

It is known (RU, patent 2197701, publ. 27.01.2003) a barrier device that contains a system of balloons, cables holding balloons at a height of 120 ... 150 m, a thin nylon network with cells 1.0 ... 1.3 m, located between balloons, and anti-personnel fragmentation mines fixed between the grid nodes, as well as regular aerosol means mounted on a nylon grid, and a control system for launching aerosol means.

The disadvantage of this analogue is that the probability of defeating air attack means does not fully satisfy the requirements for survivability of the protected object, since even with low speeds of approach due to the inertia of the fire of anti-personnel fragmentation mines (NOM), enemy air attack means can go away with a high probability outside the affected area with fragments.

It is known (RU, patent 2273818, publ. 10.04.2006) a barricade device containing barrage balloons, cables holding balloons at a height of 120 ... 150 m, a thin nylon network with cells 1.0 ... 1.2 m, light anti-personnel fragmentation mines actions fixed between the nodes of the grid, the grid-sensor for detecting enemy air attack means, in addition, it is additionally equipped with active protection means installed evenly between the nodes of the grid-sensor, and a detection radar placed on a cable that connects the aerostat you.

The known device operates as follows.

In advance, in a threatened period, install the proposed device in front of the protected object. When approaching the enemy’s air attack means towards the object, the remote launch system launches aerosol means, which form a vertical aerosol curtain in 30 ... 40 s, as a result of which the probability of detection of the protected object is reduced. When approaching enemy high-speed air attacks (70-700 m / s) at a distance of ≈50 meters, a detection radar detects targets and, after 0.07 s, shoots active weapons that form a bunch of damaging elements to destroy the target. If the enemy’s air attack means overcome the auxiliary nylon network (sensor), then anti-personnel fragmentation mines mounted on the main grid are triggered.

A disadvantage of the known technical solution can be recognized as its complexity and, therefore, low reliability.

The specified decision was taken as the closest analogue.

The technical problem, solved using the developed method, is to improve the country's defense.

The technical result achieved by implementing the developed method is to increase the protection of objects from attack by unmanned aerial vehicles and their weapons.

To achieve the indicated technical result, it is proposed to use the developed method of counteracting the fulfillment of tasks of an unmanned aerial vehicle using at least one or a group of network carriers on which a network is fixed with the possibility of folding, deployment and separation oriented vertically relative to the earth’s surface, and at least at least one carrier is attached to at least one network designed to detain a bomb dropped by an unmanned aerial vehicle or countering other hazards emanating from him and arranged to take when deploying either a horizontal or a horizontal position relative to the ground, and the network attached to the carriers with the ability to reset the capture of flying objects.

As a network carrier, an aerostat, a mini-airship, a drone, and so on can be used.

In some embodiments of the developed method, network carriers (preferably aerostats or balloons) with an extensive network are stationary, both with the possibility of attaching a cable to the ground and independently holding a given place.

In some embodiments of the developed method, a group of network carriers (preferably mini-airships or drones) with a deployed network are moved along a given route, including in the direction of flying unmanned aerial vehicles.

In some embodiments of the developed method, they additionally use means, including those fixed on the network or on its carriers, for early detection of unmanned aerial vehicles, as well as threats from them. It can be radars or multichannel optoelectronic systems.

In some embodiments of the developed method, a fine mesh network is used with additional processing, which allows delaying or neutralizing hazardous substances sprayed or spilled from an unmanned aerial vehicle. So, in particular, on the surface of the fine mesh can be applied a chemical substance that binds toxic substances sprayed by a drone.

The network can be made using electrically conductive material. This makes it possible to use electric potential fields to detain steel unmanned aerial vehicles, and to prevent chemical or biological hazards, to "burn" harmful substances that have got into it using an electric current of various frequencies and strengths transmitted through such a network, including the formation of plasma.

In some embodiments, the network may be secured with a controlled change in the angle of inclination relative to the ground. This allows you to optimize the options for the detention of unmanned aerial vehicles and / or dropped their weapons elements.

In some embodiments of the method, a sensor is additionally used that detects a foreign object entering the network. The sensor is preferably fixed to the network. The use of such a sensor allows you to timely lower the network to remove delayed aircraft from it.

Preferably, when implementing the method, network carriers are used that are configured to provide the most secure fit in the event of an accident.

When implementing the developed method, additional networks used for media protection can be used.

Networks may additionally contain deterrents

birds.

The network can be configured to turn on the backlight to prevent collisions with non-hostile objects.

Consider the method in more detail:

In principle, all networks are the same, that the net is a chain-link, that the net for fishing is their task not to miss / delay everything that is larger than the size of their cell. Specific tasks differ. In this case, you must not miss the small, low-flying low-speed target, as well as the means of destruction delivered by such devices.

This network (in a group, echeloned) is lifted on small, controlled or autonomous carriers of the network (for example, an aerostat, a drone, a helicopter, an airplane, etc.) to the desired height above the protected object (for example, a city square for public holidays on holidays). Further, holding the set height independently (or by a cable from the ground), taking into account weather conditions, open the network. It is possible, as indicated earlier, not only the static position of the carriers, but also their movement along a given route or on duty at given points without revealing the network.

When an unmanned aerial vehicle enters the network, it gets entangled in it and ceases to function. Additional means (a special form of the network, special adhesive, hooks, etc.) or even means that cause the destruction of the caught (for example, explosive packets triggered by the sensor for getting into the network) can be used to prevent falling of the caught

The hit to the network is detected by sensors (which can be located both on the media and on the network) and the medium can move to a specified safe place to check what has been caught, and another medium with the network will take its place. Or he can drop a network with a caught and fixed drone and reveal another one.

The grouping of such protective equipment can be placed, for example, on the roofs of houses and switched on at a given time, independently of target detection sensors or by command.

The grouping may also include means for detecting such unmanned aerial vehicles (for example, micro radars, sound sensors, passive radars, means of visual observation with pattern recognition) (because to solve the problem there is no need for long range) - they can be located on small media with control installed at convenient points (including stationary, receiving power via cable) according to which the trajectory of the movement of targets will be autonomously calculated and instructions will be issued for opening networks and launching tron interceptor.

In addition, networks can be stretched between houses constantly, at a height that would not interfere with the life of the city.

Thus, it is possible to quickly, cheaply and simply block the most dangerous areas from the attack of unmanned aerial vehicles, both from single and from their groups.

A feature of this proposal is the presence in the set of networks not only for vertical installation, but also for installation at any angle, which is important in a city.

The most important is the horizontal installation of networks with small cells since a case in Syria showed that these drones drop miniature bombs with target elements over the target and such a horizontal network can effectively intercept these bombs at a safe distance and prevent them from exploding or reduce their damaging effects.

In addition, to prevent an attack using the spraying of hazardous particles (such as biological weapons) of aerosols or liquids, such a protection system can be equipped with a quick-tension kit for a special network with small impregnated cells to prevent people from getting these substances. It is also possible to include gas detector detectors in the group to determine such a threat, to quickly alert and select suitable means of dealing with it.

Also, to combat a chemical and biological threat, networks with a minimum cell size, which would consist of conductors through which a command of a current of a certain frequency and power, and which, if a threat were identified, could eliminate it by “burning” such a cloud, are proposed reducing its danger.

To prevent the destruction of civilian drones and authorized vehicles, there is a friend-or-foe identification system, as well as a collision warning system (for example, the backlight for the network and carrier)

To prevent birds from entering the network, repellers are used as part of the group.

Also, networks can be installed taking into account the protection of the carrier itself from dangerous objects entering it.

To reduce the risk of the network represented by the carrier itself in case of a possible failure and fall, it is possible to use security systems, for example, using parachutes and dividing the device into small non-dangerous parts.

Claims (8)

1. A method of counteracting the performance of tasks by an unmanned aerial vehicle using one or a group of network carriers, on which a network is fixed with the possibility of folding, deploying and separating, oriented vertically relative to the earth’s surface, characterized in that at least one carrier is fixed to at least one an additional network designed to detain bombs dropped by an unmanned aerial vehicle or to protect against spraying or spilling from an unmanned aerial vehicle apparatus of hazardous substances and made with the ability to take when deployed horizontal or close to horizontal position relative to the surface of the earth, while the network is attached to carriers with the ability to discharge when capturing flying objects. 2. The method according to p. 1, characterized in that the network carriers with a deployed network are stationary. 3. The method according to p. 1, characterized in that a group of media with a deployed network is moved along a predetermined route, including in the direction of flying unmanned aerial vehicles. 4. The method according to p. 1, characterized in that they additionally use the means, including those fixed on the network or on its media, for the early detection of unmanned aerial vehicles, as well as threats from them. 5. The method according to p. 1, characterized in that they use a fine mesh network with additional processing that allows you to delay or neutralize hazardous substances sprayed or spilled from an unmanned aerial vehicle. 6. The method according to p. 1, characterized in that they use a network made using electrically conductive material. 7. The method according to p. 1, characterized in that the network is fixed with the possibility of a controlled change in the angle of inclination relative to the ground. 8. The method according to p. 1, characterized in that it additionally use a sensor that detects the ingress of a foreign object into the network.