RU2651319C1 - Method for armored vehicles protection and device for its implementation - Google Patents

Abstract

FIELD: protective devices.

SUBSTANCE: group of inventions relates to a method of protecting objects of armored vehicles and a device implementing the method. Method consists in setting the depth of the masking aerosol screen by sequentially ejecting from the hull of a grenade of aerosol-forming burning elements with masking properties in the visible range of wavelengths and ejected in the direction opposite to the grenade movement. After aerosol screen setting has been set up, the grenade body and the block of ready-for-damage elements are crushed by detonating the explosive charge of the grenade. Circular fragmentation field is formed. Device contains mortars, charged with grenades in the form of a cylindrical cup with pyrotechnic aerosol-forming equipment, pyro-retarders, propellent and expelling charges. Grenade body is made of two rigidly threaded metal cylindrical sections. In the first section closest to the propellant charge, an aerosol-forming equipment is placed, and the second section contains a block of ready-made striking elements, a charge of an explosive and a small-sized cumulative unit.

EFFECT: increased protection of armored vehicles is achieved.

7 cl, 1 dwg

Description

The group of inventions relates to the field of weapons and can be used to protect objects of armored vehicles.

One of the particular criteria for increasing the technical level of the method of protecting objects of armored vehicles is to increase the interference effect of a tank-dangerous manpower located at a firing position, using melee weapons, for example, hand-held anti-tank grenade launchers or rocket-propelled anti-tank grenades.

One of the main areas of protection for armored vehicles is a non-contact protection method, for example, interference action (withdrawal, distraction, masking) and the destruction by standard armaments of armored vehicles located at firing positions of tank dangerous personnel using melee weapons (hereinafter referred to as tank dangerous personnel) , for example, hand-held anti-tank grenade launchers or rocket-propelled anti-tank grenades (hereinafter - RPGs). Functions to ensure camouflage are assigned to smoke grenade launch systems of objects of armored vehicles [System 902. Technical description and operating instructions E 902.00.000 TO. - M .: Military Publishing House, 1980. - 22 p.].

A known method of protecting objects of armored vehicles by placing smoke screens in the visible and infrared wavelengths of the spectrum, providing distraction, removal of missile equipment of high-precision weapons and masking the object [Prospectus of the company "Schweizerische Munitionsuntemehmung", (Switzerland), "76 mm smoke grenade" Maske ", 1994], which consists in creating an aerosol curtain, which due to the high temperature of the burning aerosol-containing equipment has a significant specific output in the infrared range of the spectrum, as well as providing masking an object in the visible wavelength range. In the known method, the formation of an aerosol curtain occurs due to the explosion of aerosol forming grenades, thrown in the direction of the threat, in the air. To implement this method, the grenade contains a housing in which propelling and explosive charges are placed, an explosive charge initialization device, pyro-retarders and aerosol-forming equipment.

There is a method of setting camouflage curtains when a grenade, after falling onto the ground, releases one or several elements enclosed in separate shells from its body, igniting aerosol-containing equipment in them [Prospectus from Etienne Lacroix Defense (France), GALIX 13 system , 1994]. Aerosol formation occurs due to the release of the resulting gases from the shell of each element through a special nozzle. At the same time, a curtain spreading along the ground is created at the location of the elements. To implement this method, the grenade contains a housing in which propellant and explosive charges are placed, an explosive charge initiation device, pyro-moderators and aerosol-forming equipment.

The disadvantages of these methods and implement them designs is that:

1) the dimensions of the aerosol-forming curtain depend significantly on the direction and speed of the wind and do not allow the effective protection of the object with a limited number of grenades;

2) the interference effect on the actions of tank dangerous manpower created by a masking aerosol curtain is limited by its sufficiently short duration, which makes it possible to re-attack an object of armored vehicles;

3) there is no impact on tank-dangerous manpower and RPGs at the firing position;

4) the functions of barrage fire counteraction to the actions of tank-dangerous personnel are assigned to the individual defense systems of an object (standard, main and (or) auxiliary, armament) and, as a result, the expendable resource of the individual defense complex of an object is not ensured;

5) the functions of a counter preemptive strike against an attacking RPG are assigned to systems designed to force impact on an attacking RPG, for example, active defense complexes;

6) does not exclude the residual action of an attacking RPG on an object of armored vehicles after a defense cycle, determined by the combination of properties of the object - a complex of active defense and armor.

A technical solution is known [RF patent No. 2187062, IPC ⁷ F41H 9/06, F42B 5/155, 2000], which proposes a method and device for protecting an object of armored vehicles, which is the closest technical solution to the proposed group of inventions and selected by the authors as a prototype .

A way to protect the object of armored vehicles is to set up masking aerosol curtains by dispersing aerosol-forming pyrotechnic burning elements from grenades, thrown in the direction of the threat. The depth curtain is formed by alternately ejecting grenades from the body of the grenade, on an ascending stable section of its flight, airborne burning elements connected to each other in groups in the direction opposite to the flight direction, at a speed less than or equal to the speed of the grenade, while the front curtain is formed by dividing groups of burning elements into individual elements of irregular aerodynamic shape, followed by their braking and aerodynamic dispersion.

The device for protecting an object of armored vehicles contains mortars charged with grenades, equipped with aerosol forming, pyrotechnic propelling and ignition-blow charges. The body of the grenade is made in the form of a metal cup with a pyrotechnic charge located in it, assembled from non-shell tablets, each of which forms a group of ready-made combustible elements of irregular aerodynamic shape, between which radial and central channels are arranged. Inside the latter there is an ignition-blow-out charge equipped with a moderator with the possibility of interaction with a propelling charge located in the removed bottom, held in the tail part of the glass by a locking device with a dosed destruction force.

In the initial state, the grenade is located in the barrel of the mortar, mounted rigidly on the body of the object. When a threat is detected, a signal is sent to the electrocapsule sleeve of a grenade igniting a propellant charge. The grenade is thrown out of the mortar and flies on an ascending section of the trajectory, at the calculated point of which the bottom of the grenade is removed by the operation of an ignition-blow charge and the ignition of pyrotechnic tablets, which decompose into burning elements and create an aerosol formation.

The advantage of the prototype is to increase the effective time of the masking aerosol curtain.

The disadvantages of the known technical solutions remain:

1) there is no impact on tank-dangerous manpower and RPGs at the firing position;

2) the functions of barrage fire countermeasures against the actions of tank-hazardous manpower are assigned to the individual defense complex of the object (standard, main and (or) auxiliary, armament) and, as a result, the expendable resource of the individual defense complex of the object is not ensured;

3) the functions of the counter preemptive strike against the attacking RPGs are assigned to systems designed to force impact on the attacking RPGs, for example, active defense complexes;

4) does not exclude the residual action of an attacking RPG on an object of armored vehicles after a defense cycle, determined by the combination of properties of the object - a complex of active defense and armor.

The technical task of the group of inventions is to increase the efficiency of the interference effect of grenades of smoke grenade launchers of armored vehicles located at a firing position of a tank-dangerous manpower using melee weapons, for example, hand anti-tank grenade launchers or rocket-propelled anti-tank grenades, by defeating them or suppressing with a circular fragmentation field formed by under the action of detonation products of the explosive charge grenades from body elements and ready-to-use striking elements nt grenades, moving in the direction of movement of the grenade and increasing in radius.

The task of the group of inventions is solved as follows.

In a method of protecting objects of armored vehicles, including setting up a masking aerosol-forming curtains in depth by alternately ejecting aerosol-forming burning elements connected to each other in groups in a direction opposite to the direction of flight at a speed less than or equal to speed from the grenade body in an ascending stable section of its flight flight of a grenade, while the curtain along the front is formed by breaking up groups of burning elements into separate elements of irregular aerodynamic shape with Following their braking and aerodynamic dispersion, a new one is that the defeat or suppression of a tank-based manpower located at a firing position using melee weapons, for example, hand-held anti-tank grenade launchers or rocket-propelled anti-tank grenades, is carried out by a circular fragmentation field formed by the explosive detonation products grenades from body elements and ready-to-use striking elements of a grenade moving in the direction of movement of the grenade and increasing in radius.

In the device of the smoke grenade launch system of armored vehicles containing mortars loaded with grenades in the form of a cylindrical cup with pyrotechnic aerosol-forming equipment, propelling and ignition-blow charges and pyro-retarders, the new thing is that the grenade body is made of two metal cylindrical sections rigidly connected by a threaded joint. while an axial tube is placed in the first section nearest to the propellant charge, around which smoke-generating equipment is located in the form of segments assembled into sets radially separated and fixed by a piston and a bottom, having a pyrotechnic connection with a pyro-retarder of an axial tube, a piston with an axial tube passing through it is placed over said segments, in which an outgoing charge having a pyrotechnic connection with a pyro-retarder of an axial tube is coaxially mounted , a second section is placed above the first section, containing a block of ready-made striking elements, a bursting charge, and a small-sized cumulative unit pyrotechnically connected with a pyro-moderator m logabaritnogo cumulative assembly mounted in the upper part of the axial tube.

The body of the grenade can be made of high-fragmentation steels 60C2, 80C2, 80G2S.

The grenade body can be made in the form of a steel cylindrical glass with half-set crushing into striking elements of a rational shape and mass by means of longitudinal and transverse grooves formed during their manufacture on the inner surfaces of the walls of the grenade body sections, creating stress concentrators in which it is divided into fragments of a given form and fractional composition.

A block of ready-made striking elements can be made in the form of a cylindrical spiral with a given step of the annular layer, while in the intervals between the turns, ready-made striking elements made of metals capable of burning in oxygen in the air, for example aluminum, magnesium, beryllium, zirconium, titanium, or their alloys, for example, an electron alloy, and the width of these striking elements is equal to the width of the gap between the turns of the spiral.

The block of ready-made striking elements can be made in the form of a cylindrical spiral from an extended profile with a generatrix of a given shape winding a spiral with dense axial laying of turns with oriented formation of transverse fault surfaces under the influence of detonation products of an explosive when the shell is stretched.

A block of finished striking elements can be made in the form of a steel cylindrical glass with a half-set crushing of its body into striking elements of rational shape and mass by means of longitudinal and transverse grooves formed during its manufacture from the outer and inner surfaces of the cylinder walls, creating stress concentrators in which it is oriented separation into fragments of a given shape and fractional composition.

The inventive method of protecting objects of armored vehicles and a device for its implementation has a combination of essential features not known from the prior art for methods and devices for this purpose, which allows us to conclude that the criterion of "novelty" of the group of inventions.

The inventive method of protecting objects of armored vehicles and a device for its implementation, according to the applicant and the authors, meets the criterion of "inventive step", because for specialists, it does not explicitly follow from the prior art, i.e. not known from available sources of scientific, technical and patent information at the filing date.

The group of inventions is illustrated using the figure.

The figure shows the design of a fragmentation-aerosol-forming grenade, which is part of the device.

The fragmentation-aerosol-forming grenade includes a metal case made up of sections 1, 2, a bottom 3 with an electric igniter 4 and a propelling charge 5. Section 1 is threadedly connected to section 2. In the volume of section 1, formed by the section body and bottom 3, the outer the diameter of the section casing, and along the inner axial tube 6 fixed in the front wall of the section 1 casing, aerosol-forming equipment 8 is placed, having pyrotechnic connection through the openings 9 with the pyro-moderator 12 of the axial tube 6, in the form of segments, with taken in sets radially separated and fixed by a piston 10 mounted coaxially with the axial tube 6, in the front of the section 1, and the bottom 3. In the piston 10 coaxially with the axial tube 6, a kick charge 11 is installed, having a pyrotechnic connection with the pyro-retarder of the axial tube 12. In the volume of section 2 of the grenade body, formed by the outer diameter of the body of section 2 and the front wall of section 1, a block of ready-made striking elements 13 is placed in diameter, inside of which an explosive charge 14 with a small cumulative site is placed along the axis 15, located in the lower part of section 2 and having a pyrotechnic connection with a pyro-moderator of a small-sized cumulative assembly 7, mounted in front of the axial tube 6.

The group of inventions works as follows.

In the initial position, the grenade is located in the mortar barrel of the device for launching smoke grenades of objects of armored vehicles, for example, system 902, mounted rigidly on the body of the object. The electro-contact device of the mortar, which supplies power to the elements of the grenade fire circuit, is connected to a grenade launch device controlled by an operator or a tank dangerous personnel detection device.

When an operator or a detection device detects a tank-hazardous manpower, a control signal is supplied to the electrical contact device of the mortar. The signal received on the electric igniter 4 of the bottom 3 of the grenade initiates the propellant charge 5. Under the influence of the pressure of the combustion products of the propellant charge 5, the grenade is ejected from the mortar and moves along an ascending path. At the same time, a pyro-moderator of the axial tube 12 is initiated through the hot gases of the propellant charge 5 through the calibration hole of the bottom sleeve 3. At a predetermined distance determined by the pyrocomposition and the duration of the action of the pyro-moderator of the axial tube 12, aerosol-forming equipment segments are initiated through the calibration holes 9 of the axial sleeve 6 by the combustion products of the pyro-moderator of the axial tube 12 8 and a pyro-moderator of a small-sized cumulative unit 7. At the same time, a kick charge 11 is initiated, hot gases which is pressed on the piston 10 and through the piston 10 to the bottom 3, destroying the calibrated rolling of section 1, making its separation. Under the pressure of the combustion products of the expelling charge 11 acting on the piston 10, the aerosol forming equipment 8 is sequentially released into the atmosphere in the direction opposite to the movement of the grenade, forming an aerosol masking curtain in the atmosphere in the form of a volumetric smoke cloud saturated with burning elements. Sinking down on the underlying surface, the segments of the smoke-forming equipment, while continuing to burn, reliably connect the smoke cloud with the underlying surface, masking the object of armored vehicles.

At a given distance, determined by the pyrocomposition and the time of action of the pyro-moderator of the small-sized cumulative node 7, a small-sized cumulative node 15 is initiated, forming a cumulative stream moving at a speed of 10 to 12 km / s along the axis of the explosive charge. When the top of the cumulative jet meets the charge of the explosive, a continuous local initiation of the detonation regime is carried out, a detonation wave close to conical is formed in the explosive charge, which ensures the angle of approach of its front to the inner surface of the block of semi-finished striking elements within 8-15 °. The block of semi-finished striking elements 13 and the material of the grenade body are loaded, intense acceleration of the striking elements obtained by the destruction of the block of semi-finished striking elements in the axial and radial directions occurs, while the body begins to collapse into separate elements, forming, together with the semi-finished striking elements, a circular fragmentation field moving in the direction of flight of the grenade and increasing in radius.

The implementation of the proposed group of inventions will increase the effectiveness of the interference effect of grenades of devices for launching smoke grenades of objects of armored vehicles located at the firing position of tank-hazardous manpower, using melee weapons, for example, hand anti-tank grenade launchers or rocket-propelled anti-tank grenades, by masking an object of armored vehicles with a masking aerosol curtain the depth formed by the sequential ejection of grenades from the hull at the ascending stable m section of its flight of aerosol-forming burning equipment in the opposite direction to the flight direction, at a speed less than or equal to the grenade’s flight speed, and subsequent, with a delay after creating a masking aerosol curtain, defeating or suppressing tank-dangerous manpower in a circular fragmentation field formed in a downward stabilized section flight of a grenade under the influence of detonation products of an explosive charge of a grenade from hull elements and ready-made striking elements of a grenade moving along direction of flight of the grenade and increasing in radius.

The claimed method of protecting objects of armored vehicles and a device for its implementation, according to the applicant and the authors, can be reproduced using modern equipment and technologies, which allows us to conclude that the criterion of "industrial applicability" for the claimed group of inventions is met.

Claims (7)

1. A method of protecting objects of armored vehicles, which consists in staging the depth of the masking aerosol curtain by successively ejecting aerosol-forming burning elements that are masked in the visible wavelength range and are emitted in the direction opposite to the movement of the grenade, which is thrown in the direction of the grenade threat from the body of the grenade, that after the installation of a masking aerosol curtain with a delay at a given distance and height, the grenade body and the finished block are crushed detonation charge reflects elements explosive grenades, and the circular form shrapnel field consisting of individual housing elements and finished submunitions grenades, grenades moving in the direction of flight and at an increasing radius. 2. A device for protecting an object of armored vehicles, containing mortars charged with grenades in the form of a cylindrical cup with pyrotechnic aerosol-forming equipment, propelling and ignition-kick charges and moderators, characterized in that the grenade body is made of two metal cylindrical sections rigidly connected by a threaded connection, while in the first section closest to the propellant charge, an axial tube is placed, around which smoke-generating equipment is located in the form of segments assembled in burs radially separated and fixed by the piston and the bottom, having a pyrotechnic connection with the axial tube pyro-retarder, on top of said segments there is a piston with an axial tube passing through it, in which a kick charge is installed coaxially, having a pyrotechnic connection with the axial tube pyro-retarder, a second section is placed above the first section a section containing a block of ready-made striking elements, a bursting charge and a small-sized cumulative assembly pyrotechnically connected to a pyro-moderator installed in front of sowing tube. 3. The device according to p. 2, characterized in that the body of the grenade is made of high-fragmentation steels 60C2, 80C2 or 80G2S. 4. The device according to claim 2, characterized in that the grenade body is technologically made with semi-predetermined crushing into striking elements of a rational shape and mass by means of longitudinal and transverse grooves formed during their manufacture on the inner surfaces of the walls of the grenade body sections, creating stress concentrators in which its oriented division into fragments of a given shape and fractional composition. 5. The device according to claim 2, characterized in that the block of ready-made striking elements is made in the form of a cylindrical spiral with a given step of the annular layer, while in the intervals between the turns, ready-made striking elements made of metals capable of burning in oxygen of the air are installed, for example aluminum, magnesium, beryllium, zirconium, titanium or their alloys, for example an electron alloy, the width of these striking elements being equal to the width of the gap between the turns of the spiral. 6. The device according to p. 2, characterized in that the block of semi-finished striking elements is made in the form of a cylindrical spiral from an extended profile with a generatrix of a given shape, winding a spiral with dense axial laying of turns with oriented formation of transverse ridges of nominal fault surfaces under the influence of explosive detonation products when stretching the shell. 7. The device according to claim 2, characterized in that the block of semi-finished striking elements is made in the form of a steel cylindrical glass with a given crushing of its body into striking elements of rational shape and mass by means of longitudinal and transverse grooves formed during its manufacture from the outer and inner surfaces of the cylinder walls creating stress concentrators, in which it is divided into fragments of a given shape and fractional composition.

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