RU2387945C2 - Method to protect combat armored vehicle and its crew against high-rate weapons, or against injury or capture by enemy troops and device to this end - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: invention relates to protection of combat armored vehicles (CAV) using throwers. Proposed method consists in affecting enemy personnel nearby or directly on CAV by onboard weapons including dynamic-type protection device (DPD) mounted on CAV. At least one operator of the crew initiates blasting of explosive of at least one element 4 of DPD directed towards enemy personnel 2. Proposed device comprises DPD suspended onto or built in CAV including elements 4 distributed over the armor area and directed in different directions. Every element 4 comprises explosive, explosive detonator, one or more throwing solid bodies and control of weapons 8 detection, weapons data processing and selective outputting of signals to aforesaid detonators of elements 4 directed towards weapons 8. The device includes also system or subsystem of forced or selective initiation of detonators of DPD elements.

EFFECT: higher combat capacity.

12 cl, 8 dwg

Description

The invention relates to armored vehicles, mainly to tanks, and in particular to means of their protection and defense using throwing devices.

As a rule, when the enemy manpower appears directly on or near an armored vehicle (“on armor”), in order to destroy or capture the crew and the landing force (if any) or capture the machine as military equipment, the latter are forced to passive actions (to pull up hatches and wait for outside help, especially if the car has lost mobility), as the use of handguns through open hatches under the enemy’s sight at such a short distance is ineffective, and often practically useless.

There is a method of protecting an armored vehicle (tank) and its crew from defeat or capture (as well as variants of the device for implementing the method), which consists in influencing high-speed technical means of destruction approaching the vehicle, for example, artillery shells, anti-tank grenades and rockets, damaging and / or weakening factors of the hinged or integrated into the armor design of the dynamic type of protective device (ZUDT or "dynamic protection", "reactive armor", "explosive reactive br onya ”and other variants of the name). In this case, automatically, i.e. by means of an automatic response system (using, in particular, registration of an alternating magnetic field created by attack means, built-in inductors, or radar of the upper hemisphere of the surrounding space), differentiated (selective, based on the target orientation or its damaging factors such as a cumulative jet or metal core ) initiation of explosive (BB) elements of the protective device, which generates the said damaging and / or weakening fact s (high explosive, dynamic, dynamic high-explosive or cumulative action) [1-5].

But passive protection in its modern form is not used to destroy manpower. Not found and patent literature sources of information with relevant information.

There is also a method of protecting an armored vehicle and its crew from being hit by high-speed means of destruction (and variants of a device for its implementation), which consists in influencing an approaching projectile by the damaging factors of airborne weapons, made in the form of a system of multidirectional launching devices for counter-shells (shrapnel or high-explosive fragmentation) grenade) and an automatic detection and control system based on a radar installation and / or special sensors. In this case, automatic and selective, at the choice of automation, launch of at least one of the countershells from the launching device oriented towards the enemy’s shell occurs. At a distance safe for the car and its crew (a few meters from the car is the “security sector”), the countershell automatically explodes, hitting the projectile, weakening its damaging factors or changing its trajectory [4-6].

But active defense (with active defense complexes - KAZ) is also not used to destroy enemy manpower. Especially for our case, the location of enemy manpower "on the armor" or in the immediate vicinity of the vehicle (see. "Security Sector"). Moreover, as the costs of using KAZ, its work is sometimes accompanied by the defeat of its own infantry escorting tanks [7].

Closest to the claimed method, i.e. A method with a close purpose and a number of common essential structural features is a method of protecting the crew of an armored vehicle from high-speed means of destruction or from defeat or capture, in which the manpower of the enemy, located directly on this vehicle or near it, is affected by the damaging factors of anti-personnel fragmentation grenades (hand-held F-1 in the amount, usually up to 12 pieces, or in under-barrel, thrown by small arms) and personal small arms (machine guns, pistols, revolvers), provided in the armored vehicle for the defense of the crew, and for the landing, for attack and defense. In this case, grenade throwing is carried out, naturally, through fully or partially open hatches or doors (if any) [8].

However, this method does not coincide with the claimed purpose and, therefore, cannot be taken for its prototype.

In addition, he is characterized by the above-mentioned shortcomings, especially the fact that attempts to shoot the enemy from personal small arms through the hatch (see the second paragraph above) are also usually ineffective.

The task to which the claimed invention is directed is to improve the tactical and technical characteristics of a tank or other armored vehicle by expanding the capabilities of protecting the machine itself and members of its crew and landing force (if any) from destruction or capture by the enemy, who found himself directly on this car ("on the armor") or directly next to it.

The solution to this problem is achieved by the fact that the method of protecting an armored vehicle and its crew from high-speed weapons or from defeat or capture by enemy’s manpower consists in influencing the enemy’s high-speed weapons or manpower, located directly on or near the armored vehicle, with damaging factors a dynamic-type protective device mounted on an armored vehicle, while in the case of protection against defeat or capture by the enemy’s living force, noe selective and, optionally, at least one crew member, or a third-party operator initiating explosive, at least one of the elements of the dynamic type safety device oriented in the direction of manpower.

In other words, the claimed method as a sequence of operations is as follows.

Based on the information obtained in any way (in particular, by observing via an on-board optical observation system of the vehicle) information about the location of the enemy’s manpower directly on the vehicle (“on the armor”) or near the vehicle, one of the crew members of the vehicle (or an external operator, if any) initiates explosives of at least one of the elements of a protective device of a dynamic type (ZUDT) oriented (directed) towards the said manpower of the enemy. Local actuation (forced, selective way) of a missile defense system leads to the impact of damaging factors (metal plate, explosive action of explosives, etc., depending on the "filling" of elements of a missile defense system) on the enemy’s manpower and destroys, injures or shells it (in the latter cases - with the possibility of capture).

Since the well-known variants of ballistic missile systems are not adapted, in their current form, to perform the functions of “clearing the armor from the enemy’s manpower”, and in the process of patent and literary searches, no other known devices were found that could be used to solve the problem, it is advisable to take the most similar version of ZUDT as the base device and improve (upgrade) it accordingly.

Closest to the claimed device, i.e. A device with a similar purpose and a number of common essential structural features is a device for protecting an armored vehicle and its crew from defeat or capture by enemy’s manpower, containing a mounted or integrated dynamic-type protective device, including elements distributed over armor areas and oriented (directed) in different directions, each with an explosive, its detonator and, mainly, one or more of one being thrown hard and bodies, as well as a control system for these elements, with the possibility of automatic detonator detonation being independent from each other and the formation of damaging factors outside the armored vehicle against the means of destruction of the armored vehicle, in particular artillery shells, anti-tank grenades and rockets, which includes subsystems for detecting weapons, processing information about them and selectively issuing signals to trigger detonators of oriented elements (e.g. equal) towards the means of destruction [9].

However, this device does not coincide with the claimed purpose and, therefore, cannot be taken for its prototype.

In addition, with all its positive qualities, the device is characterized by certain, partially stipulated above, disadvantages. The main thing is that there is no possibility, in parallel and independently with the automatic control system for the initiation of explosives, to force a crew or landing force to initiate and selectively initiate explosives in order to eliminate, injure, shell-shock or take flight of enemy forces “on the armor” of a vehicle and immediately near it.

Thus, unfortunately, the instructive instruction to the commanders of Russian armored vehicles remains relevant: “when the enemy threatens to seize the tank [the crew commander] organizes its defense and only when it is completely impossible to save the tank removes the crew from it with machine guns, hand grenades and brings the tank and its armament in complete disrepair ”[10].

To implement the new method, a device is claimed - ZUDT, improved by expanding its tactical and technical characteristics (capabilities). Its characteristic as an object of intellectual property:

A device for protecting an armored vehicle and its crew from high-speed means of destruction or against defeat or capture by enemy’s manpower, including a mounted or integrated dynamic-type protective device mounted on an armored vehicle, including elements distributed over the armor area and oriented in general case, in different directions, each with an explosive, its detonator and, mainly, one or more than one throwable solids, as well as a control system for these elements, performed with the possibility of independent automatic detonators detonating from each other and forming at the same time, outside the armored vehicle, damaging factors directed against high-speed weapons of the armored vehicle, in particular, artillery shells, anti-tank grenades and rockets, which include subsystems for detecting weapons and processing information about them and the selective issuance of signals to trigger detonators of elements oriented towards the means of destruction, a system of silt subsystem and forced election, optionally, at least one member of the crew or a third-party operator, triggering detonators elements dynamic type safety device oriented toward the enemy's manpower.

In order to solve the problem, the claimed device can be characterized by the following sets of additional design features (with the above main set of features):

- the forced detonator triggering system may contain an electric power source independent of the automatic triggering system of the detonators and an electric pulse shaper sufficient to trigger the detonators of the elements individually or as a group;

- with the previous set of features, the driver in the forced detonator operation system can be configured to generate an electric pulse at the output that is similar or identical to the pulse at the output of the electric pulse generator in the automatic detonator response system;

- the detonator forced actuation system may include an independent electric power source independent of the automatic actuation system, a simulated amplified threshold signal of the detonator automatic actuation system, and force detectors that are individual for each detonator, while the source, simulator, and contactor are connected in series to the input connected in series between a comparison device and a shaper of electric pulses, as part of an automatic system stems issued to detonators for their operation;

- with the previous set of features, the forced detonator triggering system can be configured to generate an electric signal at the output of the comparison device in size no less than the electric signal at the output of the comparison device in the automatic detonator actuation system;

- the forced detonator triggering system may contain sources of alternating electromagnetic fields independent of the automatic detonator triggering system in the areas of the inductance coils of the automatic detonator triggering system, for example, additional inductors with an independent power source;

- with the previous set of signs, the forced detonator triggering system can be configured to form an alternating electromagnetic field corresponding in its parameters to the electromagnetic field generated by high-speed technical means of destruction and causing the detonator to trip from the automatic system;

- the forced detonator triggering system may include a wireless device, for example, via radio channels, for detonator triggering, comprising a central transmitter located inside the armored vehicle and peripheral wireless signal receivers in elements or subsystems of a dynamic-type protective device;

- the system or subsystem of forced detonator operation may include a subsystem for detecting manpower located directly on or near this machine, at least within the limits of the action of the damaging factors of a protective device of a dynamic type;

- a subsystem for detecting manpower located directly on or near this vehicle, at least in part, can be combined with a standard on-board, for example optical, surveillance system, at least with a panoramic surveillance subsystem from the position of the crew commander of an armored vehicle;

- the subsystem for detecting manpower can be combined with on-board surveillance systems for two or more vehicles, mainly optically interconnected with the totality of features indicated by the penultimate one.

Among the known devices and methods, no such combination of essential features would coincide with the declared one. At the same time, it is due to the latter that a new tactical and technical result is achieved in accordance with the task.

The inventive device (options) and, accordingly, implemented through it the protection method is illustrated in the drawings:

figure 1 schematically shows an armored vehicle with a modernized protective device of a dynamic type (ZUDT-M), when trying to capture enemy manpower, side view, where J _a and J _p are the main impact vectors of the attacking elements of the ZUDT and ZUDT-M oriented on high-speed weapons of destruction of the machine and on manpower of the enemy (person), respectively; V _a and V _p are the solid angles (zones) of the impact of the damaging factors of the elements ZUDT and ZUDT-M during automatic and forced operation, respectively; figure 2 is the same, plan view; figure 3 - diagram ZUDT-M with an explanation of the device of its main elements and systems; figure 4 - diagram of the first, simplest version of the system of forced initiation of explosive elements in the composition of ZUDT-M (fragment); figure 5 is a diagram of a second, "indirect" version of the system of forced initiation of explosives (fragment); figure 6 is a diagram of a third, also "indirect" version of the system of forced initiation of explosives (fragment); Fig.7 is a diagram of a fourth embodiment (with additional inductors) of the system of forced initiation of explosives (fragment); Fig. 8 is a diagram of a fifth embodiment (with a radio-controlled transceiver equipment) of an explosive forced initiation system (fragment).

An armored, mainly combat, vehicle (in this example, a tank) 1 (Figs. 1, 2) is equipped with a device (see below) for the protection of machine 1 itself and its crew (not shown) and landing (if available, in the armored space) from defeat or capture by the enemy’s manpower (represented by an enemy soldier 2, armed with personal weapons).

The inventive protective device for the convenience of description further has the abbreviation ZUDT-M ("dynamic protective device type upgraded").

There is a system 3 of optical surveillance, including, in particular, a panoramic observation device from the commander of the machine (figure 1, 2).

ZUDT-M in mounted (predominantly) or built-in version is installed on machine 1 similarly to the prototype device (basic complex) and includes, first of all, elements 4 (usually a lot, in mounted version - containers). Each element 4 contains (Fig. 3) an explosive substance (BB) 5, its detonator 6 and, mainly, one or more than one missile solids 7 in the amount of one, two (in this example) or more than two, distributed over the armor of the vehicle 1 and oriented (main vectors J), in the general case, in different directions (ideally - along the entire upper hemisphere - azimuth of 180 °, elevation angle from 0 to 90 °, preferably with overlapping zones (solid angles - V _a ) of the impact of factors against means 8 of the destruction of machine 1, in particular artillery shell Dov, anti-tank grenades and rockets (figure 2).

ZUDT-M has an automatic control system 9 (it is, by analogy with the prototype, a shaper), in which, in turn, three subsystems should be distinguished:

- detection of high-speed means of destruction 8 (and, in principle, is not excluded in the further development, - additional manpower 2, which formally also refers to "means of destruction");

- processing information about them;

- selective issuing of signals for the operation of detonators 6 elements 4, oriented (vector J _a ) in the direction of high-speed means 8 of the defeat of machine 1, taking into account the zones V _a .

The detection subsystem of high-speed means 8 includes, in the application to the described specific example, an inductor 10 (Figs. 3-7), which makes it possible to induce an alternating current in it when exposed to an alternating electromagnetic field generated by means (shells) 8.

The information processing subsystem for high-speed means 8 includes (Fig. 4), as the main components, a stabilized electric power source 11 (aka “threshold voltage source”, by analogy with the prototype), an amplifier 12, and a comparison device 13.

The subsystem for selectively issuing signals to trigger detonators 6 contains a shaper 14 of electrical pulses, for example, rectangular, sufficient, after amplification by amplifier 15, for triggering detonators 6 of elements 4 (see [8], Fig. 7). Shaper 14 may be called otherwise: “threshold voltage shaper”. The winding of the inductor 10 is connected to the input of the amplifier 12.

Thus, the automatic control system is configured to automatically detonate the detonators 6 of the elements 4 and form outside the machine 1 (in the super-armored space) damaging factors directed (J _a ) against means 8: throwing plates or other solids 7 (mechanical, in particular fragmentation effect), pressure jump (high-explosive action), cumulative jets (cumulative effect), etc. depending on the composition of the elements 4. In this case, of course, the crew and, especially, the landing party (if any) are not able to intervene in the automation of the automatic system, within it “manually” initiate BB 5, arbitrarily choosing a number, one or the other element 4.

Obviously, for the most part described, ZUDT-M is similar to the prototype device - ZUDT and this is natural in the context of the adoption of the latter as the base.

ZUDT-M additionally (along with automatic system 9) contains a system (or subsystem) 16 of forced and selective, at the choice of at least one of the crew members, or a third-party operator, or spotter, detonators 6 elements 4, oriented to the side enemy manpower 2. In it, in turn, three subsystems should also be distinguished:

- detecting the enemy’s manpower 2 (and, therefore, recognizing “friend or foe”) or, in other words, detecting person 2 located directly on or near this machine;

- processing information about enemy manpower 2;

- selective issuing of signals for the operation of detonators 6 elements 4, oriented (vector J _p ) towards the manpower 2, taking into account the zones V _p .

Of course, in the presence of two parallel systems (automatic 9 and forced), there may be a variant with two independent detonators 6 within each element 4, each in its own system (not shown).

The trivial option and / or component of the manpower detection subsystem 2 is the previously mentioned “standard” surveillance system 3 and, above all, the panoramic optical devices of the commander of the machine. With a special detection system, it can be at least partially combined with a standard on-board, for example optical (3), surveillance system. The composition of the detection system may also include communicative communications (third-party "own" observers). Moreover, it can be, in a targeted sense, combined with the detection subsystem of means 8, with the formation of a physical body detection system in general and, in addition, with on-board surveillance systems of two or more machines, mainly optically interconnected.

In the simplest (most economical) case, the subsystem for processing information about the enemy’s manpower 2 can be the thinking of the crew or the landing crew controlling the ZUDT-M, based on, for example, received visual information and knowledge of the orientation plan of elements 4.

The subsystem 16 of the selective issuing of signals for the operation of detonators 6 of elements 4 oriented (vector J _p ) towards the manpower 2, taking into account the zones of V _p , can include, in the simplest versions, a parallel electrical connection (circuit) of detonators 6 of elements 4 with a source 11 (Fig. 4) or with another, with an independent power source 17 or with a source 11 of the automatic system (Fig. 4) through an amplifier 18 and individual contactors (manual switches or normally open contactors of electromagnetic relays, i.e. forced operation emye contactors) 19, and the chance of detonation for the closure. The number of contactors 19 corresponds to the number of elements 4 (the number of detonators 6) and they are connected in parallel to each other, as a rule, with one common "set" source 17-amplifier 18.

In another (second), “mediated” version of the device of subsystem 16, the main components are a power supply 11 or 17 and a shaper 20 of electric pulses sufficient to trigger the detonators 6 of the elements 4 individually or as a group (Fig. 5). Shaper 20, as well as shaper 14, may have a different name - a threshold voltage shaper (threshold pulse). The electrical pulse at the output of the driver 20 is preferably similar or identical to the pulse at the output of the driver 14 of the electrical pulses in an automatic system.

In another possible (third), even more “indirect” version of the device of the subsystem 16, the power supply 11 or 17 is connected to the input of the simulator 21 of the amplified (by the amplifier 12) threshold voltage (signal) from the coil 10, and the output of the simulator 21 is connected through parallel interconnected contactors 19 to the shaper 14 of the electrical pulses (already part of the basic, automatic system) issued to the detonators 6 for their operation (Fig.6). In this case, the electric signal (threshold) at the output of the device 21 in the forced detonator system 6 is largest, preferably not less than the electric signal (threshold) at the output of the device 13 in the automatic system of detonators 6.

The switches 19 (or manual controls) of all circuits (in an amount equal to the number of elements 4) are located mainly on the control panel 22 of the system 16.

As another embodiment of the device (fourth), the detonator 6 forced actuation system 16 includes sources of variable electromagnetic fields independent of the automatic system 9 in the areas of the inductance 10 coils, for example, additional inductors 23 with a power source 11 or 17 (Fig. 7) . In this case, the alternating electromagnetic field generated by the system 16, according to its parameters, corresponds to the electromagnetic field generated by the means 8 of the defeat and causing the detonator 6 to be triggered by the automatic system 9.

Attempts to exclude variants with wired electric communication between the parts of the device located in the reserved space and the parts placed outside the armor (elements 4) lead to a variant in which the system 16 comprises a device for wirelessly operating, for example via radio channels, detonators 6, including a central a transmitter 24 (analogue of the remote control 22) inside the machine 1 and peripheral receivers 25 (in an amount equal to the number of coils 10) of the wireless communication signals in elements or subsystems ZUDT-M.

From the above, it is obvious that the additional equipment of machine 1, which is a forced control system 16, is proposed to be installed without binding to the system or subsystems (9) of their automatic operation for their intended purpose - when approaching high-speed technical equipment 8 defeat 8.

The device operates as follows (the method of defense in a detailed exposition).

When the enemy uses high-speed means 8 of defeating machine 1 (see Figs. 1, 2), the operation of the ZUDT-M (see Fig. 3), essentially, does not differ from the work of the well-known, widely used on ZUDT tanks: the automatic detection subsystem registers the appearance of the means 8 (for example, by the interaction of the alternating electromagnetic field of the moving means 8 with the coil of the coil 10), the automatic information processing subsystem determines and evaluates ("recognizes") the means 8 (using the threshold level of electric voltage), automatically each subsystem for generating signals for detonator response when a voltage threshold is reached generates a signal that detonator 6 is triggered. As a result, detonator (detonators) 6 of corresponding element 4 (corresponding elements 4) are automatically triggered and thereby initiating explosive 5. The device receives electric power from source 11. Damaging factors (throwing plates or other solids 7, as well as the explosive action of explosives) elements reduce the effect of means 8 on the armor of the machine 1. This is the essence of the automatically working dynamic protection of the machine 1.

When the “1” armor appears on the machine 1 or in the immediate vicinity of it, the enemy’s manpower (a person 2 armed with personal weapons in FIGS. 1, 2), there is a risk of capture and / or destruction of the machine and its crew (together with the landing party, if any) ) and the inability to get rid of the "living means" of the 2 opponents by the forces of the accompanying infantry or by the damaging factors of their other combat vehicles use the "passive part" (system or subsystem 16 of forced selective firing of fuses 6). This occurs with the active participation of the crew (commander, gunner, etc.) or paratrooper (if there is 1 landing party in the car) as follows.

As part of the human detection and information processing subsystems, they receive information about manpower on and around the armor (see Figs. 1, 2), namely: friend or foe, number of soldiers, their weapons, their intentions, assessment of potential opportunities for interaction, approximate coordinates relative to elements 4 of ZUDT-M, etc., as well as the general situation in the outside space and outside of machine 1, as well as an estimate of the probability of receiving assistance from outside. In this case, they use, first of all, the “standard” optical system 3 of machine 1, including panoramic instruments in place of the crew commander. The main thing at the final stage of information processing is to determine and evaluate the relative position of people 2 and elements 4 of the ZUDT-M and the optimal (rational) sequence of exposure to the damaging factors ZUDT-M, which means the current algorithm for closing the contactors 19 on the control panel 22.

After that, if necessary, implement this algorithm, adjusting it in real time.

Within the subsystem of the selective issuing of signals by toggle switches, buttons or other manual controls 19, power is supplied to the executive circuits (explosive initiation circuits).

Further, already automatically occurring processes in ZUDT-M, depend on the version of system 16, more specifically, on its subsystem of selective signaling.

In the simplest subsystem of selective signaling (see Fig. 4), in the initiation circuit of the explosive element 4, oriented (vector J _p ) towards human 2, taking into account the zones V _p (see Figs. 1, 2), forced, selective closure ( 19) this circuit leads to the issuance of an electric signal directly from source 17 via wires (or one wire with a common bus of a certain polarity) to detonator 6, which, when triggered, initiates an explosive charge similarly to initiating this charge (5) when an automatic system 9 is triggered. Undermining element 4 generates (again l, similarly to the basic ZUDT) damaging factors: throwing plates and / or other solids 7 and a high-explosive action in the direction of manpower (person) 2, which leads to its (his) destruction, injury, contusion or (if the effect is insignificant) shameful ( if not sensible) flight beyond the limits of the action of damaging factors.

In the “indirect”, second subsystem of selective signaling to the initiation circuit of BB 5 (see FIG. 5), forced, selective closure (19) leads to the generation of a threshold voltage to the input of the driver 20 (similar to the former 14 of the system 9) or the former 14 in the case absence in the system of its own shaper 20. The shaper 20 (or 14), in turn, gives an electric pulse, for example a rectangular pulse (as in the prototype), to the detonator 6. In this case, the pulse is sufficient to trigger the latter (see figure 5). The initiation of explosives, the formation of damaging factors and the impact on the enemy’s manpower (biological object) 2 are similar to those described above.

In the “indirect”, third subsystem for selectively issuing signals to the BB 5 initiation circuit (see FIG. 6), a forced, selective circuit (19) leads to the output of a voltage to the input of the simulator 21 of the electric signal amplified by the rectifier 12 from the coil 10 (i.e. one or two steps earlier in the control circuit than in the previous, second version of the subsystem). The output voltage from the device 21 is fed to the input of the electric pulse shaper 14 (in this example, but the option with its own for the forced system, the same shaper), which, in turn, is issued to the detonators 6, is also possible.

In the fourth variant of the subsystem for selective signal output to the initiation circuit of BB 5 (see Fig. 7), a forced, selective circuit (19) leads to the supply of voltage to the input of an additional inductor 23. The alternating electromagnetic field arising around it, as a result, acts on the main inductor 10 is similar to the effect of an electromagnetic field from a moving means of destruction 8 (if the alternating electromagnetic field generated by the system 16, in its parameters corresponds to the electromagnetic field formed by means of 8 damage and causing the detonator 6 to be triggered by the automatic system 9). The induction current in the coil 10 is issued through the circuit of the automatic system 9 to the detonator 6. Otherwise, ZUDT-M operates in the usual manner described.

In the fifth, “remote” version of the subsystem for selectively issuing signals to the BB 5 initiation circuit (see Fig. 8), a forced, selective circuit (19) leads to the generation of a response signal to the detonator 6 via a wireless channel, in this example, via a radio channel: remote control 22 (with a separate embodiment) - the central radio transmitter 24 - the surrounding space - the peripheral radio 25 in the selected element 4 ZUDT-M).

Attempts to exclude variants with wired electric communication between the parts of the device located in the reserved space and the parts placed outside the armor (elements 4) lead to a variant in which the system 16 comprises a device for wirelessly operating, for example via radio channels, detonators 6, including a central a transmitter 21 (an analogue of the remote control 19 or a prefix to it) inside the machine 1 and peripheral receivers 22 (in an amount equal to the number of coils 10) of wireless communication signals in elements or subsystems of ZUDT-M.

Other options for methods and devices for their implementation are not excluded, within the framework of the claimed sets of essential features.

The choice of a specific option when using the invention depends on the range of tactical, technical and economic requirements and is made in each case.

The use of the invention allows to increase the tactical and technical characteristics of a tank or other armored vehicle, expanding the capabilities of protecting both the vehicle itself and its crew and landing force (if any) from destruction or capture by the enemy, who was directly on this vehicle ("on the armor ") or near it (near it).

Information sources

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5. Protection of tanks / V. A. Grigoryan, E. G. Yudin, I. I. Terekhin and others; under the editorship of V.A. Grigoryan. - M.: Publishing House of MSTU. N.E.Bauman, 2007 .-- S.143-177.

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Claims (12)

1. A method of protecting an armored vehicle and its crew from high-speed means of destruction or against defeat or capture by enemy’s manpower, which consists in influencing high-speed means of destruction or manpower of the enemy, located directly on or near the armored vehicle, by the striking factors of the protective device of a dynamic of the type installed on the armored vehicle, while in the case of protection against defeat or capture by the enemy’s manpower, they perform forced and selective, optional by at least one crew member or a third-party operator, initiating an explosive of at least one of the elements of a dynamic-type protective device oriented towards the enemy’s manpower. 2. A device for protecting an armored vehicle and its crew from high-speed means of destruction or against defeat or capture by enemy’s manpower, including a mounted or integrated dynamic-type protective device mounted on an armored vehicle, including elements distributed over the area of armor and oriented, in the general case, in different directions, each with an explosive, its detonator, and predominantly one or more throwable solids, as well as a control system for these elements, with the possibility of independent detonator automatic operation and the formation of damaging factors outside the armored vehicle against high-speed weapons of the armored vehicle, in particular artillery shells, anti-tank grenades and rockets, which include subsystems for detecting weapons and processing information about them and the selective issuance of signals for the operation of detonators of elements oriented towards the means of destruction, the system or subsystem and forced election, optionally, at least one member of the crew or the operator side, triggering detonators elements dynamic type safety device oriented toward the enemy's manpower. 3. The device according to claim 2, in which the forced detonator triggering system comprises an electric power supply independent of their automatic triggering system and an electric pulse shaper sufficient to trigger the detonators of the elements individually or in a group. 4. The device according to claim 3, in which the driver in the forced detonator triggering system is configured to generate an electric pulse at the output of a pulse that is similar or identical to the pulse at the output of the electric pulse former in the automatic detonator response system. 5. The device according to claim 2, in which the forced detonator triggering system includes an electric power supply independent of the automatic triggering system, a simulated amplified threshold signal of the automatic detonator triggering system, and forcibly triggered individual contactors for each detonator, the source being a simulator and the contactor are connected in series to the input of the comparison device and the electric pulse shaper connected in series to each other Ave automatic system issued to the detonators for their operation. 6. The device according to claim 5, in which the forced detonator triggering system is configured to generate an electric signal at the output of the comparison device of magnitude no less than an electric signal at the output of the comparison device in an automatic detonator actuation system. 7. The device according to claim 2, in which the forced detonator response system comprises sources of variable electromagnetic fields independent of the automatic detonator response system in the areas of inductance coils of the automatic detonator response system, for example, additional inductor with an independent power source. 8. The device according to claim 7, in which the forced detonator operation system is configured to form an alternating electromagnetic field corresponding in its parameters to the electromagnetic field generated by high-speed technical means of destruction and causing the detonator to trip from the automatic system. 9. The device according to claim 2, in which the forced detonator triggering system comprises a wireless device, for example, via radio channels, for detonator actuation, comprising a central transmitter located inside the armored vehicle and peripheral wireless signal receivers in elements or subsystems of a dynamic-type protective device. 10. The device according to claim 2, in which the system or subsystem of forced detonator operation includes a subsystem for detecting manpower located directly on or near this machine, at least within the range of the damaging factors of a dynamic-type protective device. 11. The device according to claim 10, in which the subsystem for detecting manpower located directly on or near this vehicle is at least partially integrated with a standard on-board, for example optical, surveillance system with at least a panoramic surveillance subsystem from the position of the armored crew commander cars. 12. The device according to claim 10, in which the subsystem for detecting manpower is combined with on-board surveillance systems of two or more machines, mainly optically interconnected.

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