RU2239152C1 - Hitting component of cluster ammunition - Google Patents

Abstract

FIELD: hitting components of cluster ammunition.

SUBSTANCE: the hitting component has a body, having a means of crushing into fragments in the form of circular riffles, filling of an explosive with a shaped recess with an open cylindrical bushing fastened before it, inertia fuse with a primer detonator shifted relative to the striker spring connected to the band of the aerodynamic stabilizer through a cross axle and a rotary bent shackle zigzagged around the fuse. The novelty is in the fact that the primer detonator is installed in a spring-loaded slide bar resting on a pyrotechnical lock, and a number of through slots is made in the bushing, longitudinal or inclined riffles are additionally made on the body outer surface, they form together with the circular riffles a net of evenly distributed semi-finished fragments.

EFFECT: enhanced fragmentation action of the hitting components that are safe in service handling.

3 dwg

Description

The invention relates to ammunition, and more particularly to a cluster, in the shell of which contains many individual striking elements, mainly fragmentation-cumulative effects.

The level of technology in this area is characterized by a striking element of a cluster munition containing a body filled with explosive, a cumulative recess in front of which an open cylindrical sleeve is mounted on the body, a belt stabilizer placed on the fuse and connected with a transverse axis, and means for crushing the body into fragments (cm Journal of Wehrtehnik N2, 1995, p. 41, Fig. C).

The disadvantage of this striking element is that in the case of the use of a light sleeve that provides a cumulative charge at the most favorable distance from the target surface in terms of the effectiveness of the strike, the static stability margin on the autonomous flight path is not guaranteed due to the displacement of the center of mass of the striking element to the tail.

With a forcedly short stabilizer, the length of which is limited by the free volume between the fuse body and the open cylindrical sleeve of an upstream striking element in the cluster munition assembly, the longitudinal stability of the striking elements during autonomous flight and, therefore, normal to the obstacle orientation of the cumulative funnel is not provided.

In addition, folded in half and secured by both ends on the axis of the fuse body, the belt stabilizer can be cut off from the jerk of the aerodynamic opening of the zigzag.

When approaching the target of a striking element that is not oriented normally, the cumulative funnel does not provide the specified effectiveness of the armor penetration of the obstacle.

The combat mission characteristics of this striking element are unsatisfactory due to the low efficiency of the cumulative jet, but due to the location of the focus of the cumulative recess far beyond the end of the head sleeve, since its length is minimized by the value of the overturning moment of the incoming air flow, and secondly, due to the limited area of damage by fragments cylindrical body, creating small angles of expansion of fragments and low declination of fragmentation zero.

The noted disadvantages are eliminated in the striking element of the cluster munition according to the patent RU 2137087, F 42 B 12/58, 1999, selected but the technical nature and the number of matching features as the closest analogue to the proposed.

The known damaging element comprises a housing having, on the outer surface, a means of crushing into fragments in the form of ring riffles, filling an explosive with a cumulative recess, in front of which an open cylindrical bushing is fixed, an inertial fuse including a spring-loaded detonator capsule displaced relative to the ground pin connected through a longitudinal a movable transverse axis and a curved bracket with an aerodynamic stabilizer tape zigzag laid around the fuse.

The execution of the bottom part of the conical shape with ring flutes on its cylindrical part, forming the protrusions of the semi-finished fragments of a given longitudinal crushing of the body, allowed to increase the thickness of its walls and redistribute the mass forward to an additional distance from the tail of the damaging element. This increased the area of fragmentation damage and increased the stock of static stability of the damaging element.

Placing an elongated cylindrical sleeve of light material (aluminum alloy) in front of the housing, along with increasing the area of the fragmentation field, increases the efficiency of the cumulative action of the funnel, the focal length of which practically coincides with the end face of the damaging element.

The connection of the tape stabilizer with the transverse axis of the fuse case by means of a rotatable curved bracket deformed in operation increased the reliability of the product by damping the force of dynamic opening of the tape from the zigzag, which made it possible to fix the tape at one end, thereby increasing the length of the aerodynamic stabilizer and, therefore, shift the center of pressure to the bottom of the striking element, than to increase its longitudinal stability on the path of autonomous flight.

The stock of longitudinal stability during aerodynamic stabilization of the striking element created the prerequisites for increasing the length of the head sleeve to the focal length of the cumulative funnel.

The spatially curved shape of the bracket for attaching the belt stabilizer ensures its compact laying by turning around the transverse axis on the fuse case.

The zigzag willow tape is automatically opened on the path of an autonomous flight of the striking element by the incoming air flow without overlapping, loops and twisting, over the entire length of the stabilizer.

However, the known damaging element of the cluster warhead has a number of the following disadvantages.

The kinematic connection of the sting tip with the swivel protruding beyond the dimensions of the fuse ensures that it is cocked by a belt aerodynamic stabilizer on autonomous flight, but does not guarantee safety in official handling, the careless actions of which can cause unauthorized cocking of the fuse and the operation of the striking element, for example, from accidental application of force to tape or when it falls on the assembly of cluster munitions, which is unacceptable.

Limited by the design of the cluster munition and the layout of the elements in it, the length of the body of the striking element does not allow using an elongated cumulative funnel more effective in armor penetration.

In addition, unregulated radial crushing of the body of the striking element reduces fragmentation.

The problem to which the present invention is directed, is to increase the combat power of the damaging elements of cluster munitions that are safe in official use.

The required technical result is achieved by the fact that in the known striking element of the cluster munition containing a body having crushing means on the outer surface in the form of ring riffles, filling an explosive with a cumulative recess, in front of which an open cylindrical bushing is fixed, an inertial fuse with a detonator capsule shifted relative to the floor sting connected through the transverse axis and the rotatable curved bracket with the aerodynamic stabilizer tape, zigzag laid around the fuse according to the invention, a detonator cap is mounted in spring-biased slide valve, relying on a pyrotechnic stopper and formed in the sleeve a number of through-slits, wherein the outer surface of the housing is further formed longitudinal or inclined riffle forming a uniformly distributed grid of annular riffles semi fragments.

Distinctive features have provided a solution to the task of the invention to increase the combat power of the damaging elements of cluster munitions with structural safety in official use.

The striking element is equipped with an additional safety device, the pyrotechnic stopper of which mechanically prevents the fuse from tripping (guidance) in official circulation, geometrically locking in the inoperative position (offset from the stinger) a spring loaded gate carrying a detonator capsule. The fuse is cocked only when the striking elements are ejected from the cluster munition, after the pyrotechnic stopper is ignited, ignited by an external temperature pulse when the charge of the common ammunition cartridge is triggered, which is transmitted through the through slots of the head sleeve mated to the tail of the upstream docked element along the axis of the striking element.

The formation of a grid of semi-finished fragments on the outer surface of the casing by means of additional corrugations of intersecting direction (longitudinal or inclined) ensures crushing of the casing into fragments of a given optimal mass and shape. This allows, without increasing the mass of the body of the striking element, to increase its length, increase fragmentation and place an elongated, more effective armor-piercing cumulative funnel.

In this case, the center of mass of the striking element moves to the warhead, which further increases its static stability, and as a result, the time of longitudinal stabilization of the elements in autonomous flight is reduced, which ensures the combat use of the striking elements from a lower height of their ejection from the cluster munition for a more likely target hit .

Through the slots in the head cylindrical sleeve provide ignition of the pyrotechnic composition of the stopper of all striking elements of the cluster munition from an external temperature and pressure impulse created by the action of a charge located inside the cluster munition, as a result of which the detonator capsule is automatically fed by a spring-loaded gate under the sting tip, thus removing the step protection, and the inertial fuse is ready for operation.

Therefore, each essential feature is necessary, and their combination is sufficient to achieve the novelty of quality in the form of the effect of the amount that is not inherent in the signs of disunity.

The invention is illustrated in the drawing, which shows:

figure 1 - the proposed striking element;

figure 2 - safety device fuse;

figure 3 - striking element in autonomous flight.

A congruent cumulative funnel 3 (Fig. 1), made in particular in the shape of an elliptical paraboloid, is mounted in the recess of the filling 1 of the explosive of the body 2 of the striking element. Due to the parabolic configuration of the funnel 3 elongated by 15% in the explosive filling 1 of the body 2, a greater velocity gradient is provided in the initial part of the shaped-charge jet, which is approximately 30% higher than the conical funnel of the prototype increases armor penetration.

On the outer surface of the casing 2, annular and longitudinal riffles 4 and 5 are made, respectively, which form a grid of equally distributed semi-finished fragments 6 of a given crushing.

Formed by intersecting riffles 4, 5, a grid of semi-finished fragments 6 provides redistribution to the head of the striking elements of the mass of the body 2, the length of which increases by about 7% without increasing its mass, while the atom has an open end fixed to the body 2 of the cylindrical sleeve 7 at a focal length longer cumulative funnel 3 in the shape of an elliptical paraboloid.

The bottom part of the body 2 is made in the shape of a truncated cone and is connected with a smaller fuse 8, on the transverse longitudinally movable axis 9 of which a rotary curved bracket 10 is installed. The end of the aerodynamic stabilizer band 11 is fixed on the bracket 10.

Tape 11 marks LKTP-25-200 (GOST 17667-77) with a width of 25 mm and a length of 1 m is folded in a zigzag pattern and placed is a polymer bag 12, which is laid around the fuse 8 above the bracket 10 pressed against the body 2.

When storing and transporting the striking element, its tail section is closed by a safety cap 13, which in service circulation is fixed on the body 2 by a screw 14 located inside the axis 9, preventing the longitudinal movement of the fuse 8 and the bracket 10. Before assembling the cluster munition, the screw 14 on the tail cap 13 parts of the damaging elements are removed.

In cluster munition, the tail of the striking element is placed inside the open cylindrical sleeve 7 of the upstream element, with the cap 13 being located above its annular protrusion 15 of the open end of the sleeve 7, which acts as a stiffener and a stripper of the cap 13 when separating the striking elements.

In the sleeve 7, a series of through radial slots 16 is made for communication with a safety device of an upstream striking element in the assembly of a cluster munition: a pyrotechnic stopper 17 (FIG. 2) of a gate 18 carrying a detonator capsule 19 of a fuse 8 and loaded with a spring 20. A sting tip 21 of an inertial fuse 8 is placed in the hole 22 of the gate 18.

Under the gate 18, a container 23 with a transfer detonation charge 24 is strengthened.

Before ejecting the damaging elements inside the cluster munition, a pyrotechnic charge is triggered and a pressure of 10.0-12.5 atm and a temperature of 600-700 ° C are created, which through the through slots of 16 bushings 7 ignite the pyrotechnic composition of the stopper 17 located inside the liner 7 aligned along the axis of the damaging item.

After ejecting from the shell of a cluster munition, the striking elements are undocked for separate autonomous movement to the target without a cap 13, which remains inside the head cylindrical sleeve 7, on its annular protrusion 15, above the cartridge and the striking element.

A free-flowing air stream packet 12 breaks from the zigzag of the folded tape 11, which opens, forming an aerodynamic stabilizer, and the bracket 10 is unbent, damping the braking force from the opening of the tape 11 jerkily, and occupies an axial position relative to the housing 2 (Fig. 3). In this case, the inertial sting 21 moves relative to the housing 2 to its highest position, freeing the opening 22 of the gate 18.

Further, during the combustion of the pyrotechnic composition of the stopper 17, the gate 18 is released, which, under the action of a compressed spring 20, moves the detonator capsule 19 under the tip 24 - the fuse 8 is induced.

The tape 11, which opened behind the shank of the striking element, shifts the center of aerodynamic pressure behind, providing longitudinal stabilization of the striking element on the path of autonomous flight and its almost normal position when faced with an obstacle, which is necessary for reliable operation of an inertial fuse and effective armor penetration.

When meeting the obstacle, the sting 21 inertially progressively moves downward and punctures the stationary detonator capsule 19, the impulse of action of which initiates the detonation charge 24 of the filling 1 of the housing 2. At the same time, the cap 13 is kicked out of the sleeve 7 by the pressure jump of the explosion of filling 1.

With the detonation of filling 1, the funnel 3 collapses with the formation of a cumulative jet, and the case 2 of the element is torn along the sections weakened by intersecting corrugations 4 and 5 into fragments 6 given in shape and mass, affecting the enemy's manpower.

Thus, the well-known ammunition has been structurally improved to increase combat power: the effectiveness of armor penetration and fragmentation of the striking elements, with complete safety in official use.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the invention does not explicitly follow for an ammunition specialist, showed that the new striking element is not known, and considering suitability for implementation in mass production, we can conclude that the criteria for patentability are met.

Claims (1)

The striking element of a cluster munition, comprising a housing having crushing means for fragmentation in the form of ring riffles on the outer surface, filling an explosive with a cumulative recess, in front of which an open cylindrical sleeve is fixed, an inertial fuse with a detonator capsule offset from the stinger connected through the transverse tip the axis and the rotatable curved bracket with an aerodynamic stabilizer tape zigzag laid around the fuse, characterized in that the detonator capsule is installed it is connected in a spring-loaded gate, resting on a pyrotechnic stopper, and a number of through slots are made in the sleeve, and longitudinal or inclined riffles are additionally made on the outer surface of the casing, forming a grid of equally distributed semi-finished fragments with ring riffles.

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