RU2367890C1 - Anti-radar shell - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: invention relates to ammunition designed to ensure anti-radar protection. Proposed shell comprises casing with receiver accommodating cartridge with electric igniter screwed therein. Right above the said cartridge a piston is arranged representing a cup with burster charge placed on its bottom. Stack of disks with densely packed dipole reflectors and covered with sealing cap rests upon aforesaid piston. Burster charge is arranged inside damping annular shutter and rests upon crosswise crosspiece that features central fire-transfer hole. Aforesaid electric igniter is screwed in place, inside the cartridge, via sealer interlayer to allow normal electric contact. Note here that sealer interlayer height from the shell end face makes 1/3 to 1/2 of cartridge height.

EFFECT: higher reliability of shell.

2 dwg

Description

The invention relates to ammunition, and more particularly to shells for dispersion by dispersion of materials providing radar reflection, and can be used as a means to create electromagnetic interference in order to protect aircraft from missiles with homing radar heads.

The level of this technical field characterizes a projectile for setting a combined false target according to patent RU 2239777, F42B 12/48, 12/70, 2004, containing an electric igniter placed in a glass (holder) with throttling holes aimed at propellant powder charge mounted in a cylindrical body on a transverse jumper forming a receiver and adjacent to the payload block (stack) of cassettes.

The propellant powder charge is designed to knock out the functional structure entirely from the shell of the shell.

In this case, the clip of the electric starter device with the bottom of the case is rigidly connected by a screed, on which pyro-retardants, ignition initiators, and pulse charges of throwing payloads from the cartridges are placed in the clips sequentially mounted on the clips.

To separate the cartridges in the atmosphere and the autonomous action of the payload for the intended purpose, the central screed is made with a weakened cross-section through which the gaseous products generated by the burning of the propellant are destroyed by the pressure, as a result of which the entire block of cartridges is fired from the shell of the projectile.

Cassettes with dipole reflectors around the perimeter are shielded by movable semi-cylindrical pushers that overlap the perforations of the central tube, preserving their integrity and shape.

A feature of the described design is its various configuration of sequentially connected cassettes in the fire chain with payloads for combined action or separate setting of interference by types.

The payload of the cartridges of this combined-action projectile is made in the form of biscuits of densely packed dipole reflectors and / or with a set of non-combustible plates having a coating of smoke-forming material.

Being scattered in the atmosphere, the first of them create radar interference for the detection means, and the second - false targets in the form of electromagnetic radiation in the infrared wavelength range.

However, a continuation of the advantages is an inherent disadvantage, which is expressed in the complexity of the design of the projectile, the high complexity of manufacturing, which limits the serial use for practical armament of aircraft.

The noted drawback is eliminated in the target cartridges of a simple design, designed to separately create anti-radar interference (patent RU 2231741) and for setting false targets in the form of infrared radiation sources that simulate heated units and components of military equipment (patent RU 2231742).

According to the technical nature and the number of matching features, the cartridge described in patent RU 2231741, F42B 5/15, 12/70, 2004 was selected as the closest analogue to the proposed anti-radar cartridge.

The well-known anti-radar cartridge contains a cylindrical body with a threaded electric igniter installed in the central holder of its bottom part, which is equipped with a throttle nozzle at the outlet to form a fire torch aimed at the discharge charge installed in the massive piston adjacent to the inner surface of the housing.

The piston is located on supports resting on the bottom of the housing, forming the free volume of the receiver.

A stack of functional biscuits with densely packed dipole reflectors of different lengths is installed on the piston to expand the range of absorbed electromagnetic waves of the emitter.

Biscuits are made of aluminum-metallized glass fiber with a release coating for free dispersion when dispersed in the atmosphere.

The stack of biscuits in the case is closed by a sealing cover, which is geometrically closed with the body by rolling the petals of its end.

When an electrical impulse is applied from the board of the aircraft to the electric igniter held in the launcher by the bottom flange of the cartridge, a dense narrowly directed fire force is formed by the throttle nozzle, which enters the ignition of the coaxial expelling charge, during the combustion of which gaseous products fill the receiver.

The increased pressure of the gaseous products accumulated in the receiver is distributed through the massive piston to the stack of biscuits and then to the cover, which with its longitudinal movement bends the petals of the end face of the casing, freeing the passage of biscuits emitted into the atmosphere, where they are separated.

The dipole reflectors scatter in space by an incoming air flow, creating a three-dimensional curtain of radar interference.

However, the following disadvantages are inherent in this described simple design of the anti-radar cartridge.

The massive piston and its bearings limit the volume of the receiver, which sometimes is not enough to form a delay time for throwing biscuits at a safe distance from the side, which reduces the effectiveness of the main action for the intended purpose.

When a detonating charge is triggered, the shock wave freely through the open volume of the receiver acts on the end face of the cartridge clamped in the launcher and, accordingly, on board the aircraft, which is undesirable, especially since it happens repeatedly.

In the throttle nozzle of the holder, in which the electric igniter is mounted, a fire torch is dynamically formed, which reliably ignites the outburst charge, but at the same time (especially at small calibers with minimal removal), cases of outbreak charge destruction are possible, the combustion dynamics of which varies arbitrarily, distorting the estimated throwing time of the useful load.

This can be accompanied by burning of the piston and sintering of part of the dipoles that do not disperse, which reduces the effectiveness of masking.

In addition, under conditions of cyclic heat load in combat operating conditions of supersonic aircraft in the range from minus 60 ° С to 200 ° С and increased humidity of the conditionally tight mount of the electric igniter in the casing holder, it is clearly not enough to maintain the functional reliability of the expelled powder charge.

The problem to which the present invention is directed, is to increase the functional reliability of the universal design of the anti-radar cartridge.

The required technical result is achieved by the fact that in the known anti-radar cartridge containing a housing with a receiver, in which there is a cage with an electric igniter screwed into it, over which there is a piston with an expelling charge in its bottom, on which a stack of biscuits with tightly packed dipole reflectors, according to the invention, the piston is made in the form of a thin-walled metal cup, the open end of which rests on a ledge made in the receiver, while A detonating charge is located inside the damping ring obturator and rests on a transverse jumper with a central fire-transfer hole, and the electric igniter in the cage is screwed through the sealant layer to ensure electrical contact at the place of their direct connection above the sealant layer, while the height of the sealant layer from the end of the cartridge is 1 / 3-1 / 2 of the height of the clip.

As an embodiment of the cartridge, the electric igniter is flush mounted in the clip.

Distinctive features provided an increase in the functional reliability of the universal design of the anti-radar cartridge, suitable for all applicable calibers, adapted for use in aircraft.

The execution of the piston in the form of a cup, the open end resting on a protrusion in the receiver of the housing, creates an additional receiver volume isolated by a shielding transverse jumper from the expelling charge, which provides the necessary time delay for the formation of a given pressure of the gaseous products of combustion of the expelling charge, which develops a propelling impulse that scatters the biscuit dipoles on given distance from the board.

The preferred choice of metal as the structural material of a thin-walled piston is determined by its strength, load-bearing characteristics, available manufacturing technology by means of sheet stamping. This allows you to provide with the minimum thickness of the piston the necessary performance, specified function and maximum receiver volume.

The transverse jumper inside the piston, on which the outburst charge rests, additionally acts as a screen from the direct action of the shock waves of the igniter force from the electric igniter directed through the central fire-transfer hole and dampens the pressure pulses of the gaseous products of combustion of the outburst charge generated in the receiver.

The damping annular obturator serves as the cuff for its intended purpose and additionally serves as a damping pad that dampens the shock loads of the dynamic propelling impulse on the piston and dipoles.

The installation of an electric igniter in the casing of the bottom of the housing through the sealant layer, which isolates the internal volume of the cartridge for its intended purpose, maintains its electrical contact with the housing due to the connection at the place of their direct connection above the sealant layer.

This makes it possible to use launchers with peripheral current supply along the bottom of the hull to launch radar cartridges, expanding the operational capabilities of the equipment.

The height of the sealant layer is selected in the range of 1 / 3-1 / 2 of the height of the electric igniter and, accordingly, the housing clip for the following reasons.

The height of the sealant layer in the said connection less than 1/3 does not guarantee isolation of the internal volume of the cartridge during long-term storage and in official circulation with a cyclic difference in operating temperatures in supersonic high-altitude aircraft.

When the height of the sealant layer in the said connection is more than 1/2 the height of the electric igniter, reliable electrical contact of the housing clip with the electric igniter is not ensured, which can cause failure when starting the cartridge from the installation with a peripheral current supply to the bottom end of the housing.

The installation of an electric igniter flush in the cage at the bottom of the hull, that is, without a throttling nozzle of the output diaphragm, expands the technological possibilities of using the invention with a unified ignition device on all sizes and calibres of aviation radar cartridges. At the same time, the flame torch from the electric igniter does not accelerate and therefore does not destroy the blowout charge, the ignition of which occurs stably on all caliber cartridges.

Therefore, each essential sign is necessary, and their combination in a stable relationship is sufficient to achieve the novelty of quality, that is, the technical problem posed in the invention is solved not by the sum of the effects, but by a new effect of the sum of the signs.

The invention is illustrated by the drawing, which has purely illustrative purposes and does not limit the scope of the claims of the totality of the features of the formula. The drawing shows: in Fig.1 - the proposed anti-radar cartridge; figure 2 is the same, an embodiment.

The cartridge contains a cylindrical housing 1 with a receiver 8 and with functional filling in the form of a stack of coaxial biscuits 2 of different heights, which are dipole reflectors tightly packed in a shell, which are made of aluminum metallized fiberglass with anti-adhesive coating.

In the bottom part inside the casing 1, a cage 3 is made, into which a threaded electric igniter 4 is screwed through the sealant layer 5. The height of the interlayer 5 is selected in the range from a third to half the height of the holder 3 and, accordingly, of the electric igniter 4.

On the ledge 6 of the housing 1 above the ferrule 3 is installed glass-shaped thin-walled metal piston 7.

At the bottom, inside the piston 7, a knockout charge 9 is placed, resting on a transverse jumper 10 having a central fire transfer hole 11.

Knockout charge 9 is installed inside the damping annular obturator 12, which is adjacent to the stack of biscuits 2.

In large-caliber cartridges, where the knockout charge 9 is removed from the electric igniter 4 (Fig. 2), at the output of the holder 3 a throttling nozzle 13 is made, which compresses the gaseous products generated by the triggered pyrotechnic electric igniter 4 into a dense high-speed force, guaranteed to ignite the knockout 9.

The stack of biscuits 2 from above is closed by a sealing cover 14, geometrically closed by the petals 15 from the material of the open end of the housing 1.

The anti-radar cartridge operates as follows.

When an electrical impulse is supplied from the launcher’s current supply to the electric igniter 4 directly or to the end face of the housing held by the flange, electrically connected through the ferrule 3 to the electric igniter 4, the electric igniter 4 is triggered, forming a flame force coming through the central fire transfer hole 11 of the jumper 10 to ignite the knockout charge 9.

When burning the knockout charge 9, gaseous products are actively generated, which through the hole 11 in the jumper 10 enter the receiver 8, shocklessly filling its volume, where they are mixed.

The increased pressure in the receiver 8, the powder gases distributed effect on the horizontal jumper 10, pushing a stack of biscuits 2 through the piston 7 with the obturator 12.

In this case, the shock pulses of the efforts of the longitudinal movement of the piston 7 are damped in the obturator 12, not transmitted to the biscuits 2.

The buoyancy force of the pressure of the powder gases in the receiver 8, the cover 14 is squeezed out of the open end of the housing 1, bending its locking tabs 15, freeing the passage of biscuits 2.

Next, biscuits 2 are emitted into the atmosphere, where they are separated, and dipole reflectors scatter in space in an oncoming flow, creating a masking curtain in a wide range of wavelengths of electromagnetic radiation, on which the enemy detection and guidance tools work.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the invention does not explicitly follow for a specialist in protecting objects of technology from reconnaissance and attacking means, showed that it is unknown, and given the possibility of practical serial production of anti-radar cartridges, we can conclude eligibility criteria.

The positive results of the reliable operation of the proposed design of an easy-to-manufacture cartridge on the stand and firing allow us to recommend the Customer re-equipment of camouflage means of existing aircraft and equipping them with newly manufactured ones.

Claims (2)

1. The anti-radar cartridge, comprising a housing with a receiver, in which there is a cage with an electric igniter screwed into it, over which there is a piston with a knockout charge in its bottom, on which a stack of biscuits with tightly packed dipole reflectors rests, characterized in that the piston is made in the form of a thin-walled metal cup, the open end of which rests on a ledge made in the receiver, while the knock-out charge is located inside the damping ring rim and rests on a transverse jumper with a central fire-transfer hole, and the electric igniter in the cage is screwed through the sealant layer to ensure electrical contact at the point of their direct connection above the sealant layer, while the height of the sealant layer from the end of the cartridge is 1 / 3-1 / 2 of the height of the clip . 2. The cartridge according to claim 1, characterized in that the electric igniter in the holder is mounted flush.

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