RU2398178C1 - Ir-radiation pyro round - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: proposed round comprises cartridge case accommodating functional grain closed by cover that rests on ring forming receiver above electric igniter that interacts with cartridge holder terminals on aircraft airframe. Said functional grain is arranged on screen membrane separating it from receiver. Output window of the cap with initiating charge is covered by gas-impermeable membrane while lower circular electrode is arranged on contact surface of the flange coaxial with central current lead and, via loading resistor, connected to its obturating flange isolated from top disk electrode. Proposed invention allows mechanical prevention of false closure of waste component electric circuit in its three-electrode igniter with separated connection in test and operating conditions.

EFFECT: higher reliability of aircraft anti-jam protection due to scheduled task of inner electric circuitry before use.

2 cl, 5 dwg

Description

The invention relates to ammunition, and more particularly to pyrotechnic anti-jamming cartridges, modified for electrical ignition.

The prior art is characterized by the cartridge described in patent RU 2282131, F42В 5/08, 2006, containing a sleeve with functional filling, which communicates with an electric igniter device coaxially mounted in the bottom flange, containing a central current lead mounted by means of a non-conductive sleeve in a cylindrical threaded housing adjacent to the lower of the two, separated by an insulating gasket, disk electrodes connected by a filament bridge, placed in the ignition-initiating composition.

The initiating composition is contained in a shell provided with an output window, resting on the upper electrode connected to the housing, the open end of which is sealed on the side of the sleeve’s functional charge.

A feature of the electric igniter device is the presence of a horizontal jumper, which is an obturating flange of the central current lead, which is mounted on the ledge of the housing and is geometrically connected to it by a profile sleeve, which prevents the breakthrough of hot combustion products of the igniter charge into the gun’s shutter.

The described electric igniter device serves as an autonomous assembly unit and is an independent element in the assembly of various cartridges (see patent RU No. 33642, 2003).

In technical essence, the closest analogue to the proposed pyrotechnic cartridge is the one described in patent RU No. 2231742, F42В 5/15, 12/70, 2004, which describes the pyrotechnic infrared radiation cartridge used in the cassette holder mounted on the fuselage of the aircraft for setting a false target that simulates the generated by an aerosol cloud thermal radiation from running engines.

The known cartridge contains a cylindrical body with a threaded electric igniter installed in the central body of the body, which is equipped with a throttle nozzle at the outlet to form a fire torch, directed by an igniting action on a functional pyrotechnic checker, resting through the obturator on a hollow cylindrical tray (shell), which forms the receiver, where the gaseous products of the combustion of the checkers in the cartridge accumulate.

A cylindrical checker along the perimeter has longitudinal channels developing a combustion surface, and is adjacent to the inner surface of the housing through a radial clearance, which serves for the flame transfer of the ignition pulse.

The depth of the longitudinal channels of the checker is slightly larger than the size of the obturator ring, for guaranteed communication of the receiver with the outer surface of the checker when ignited.

When an electrical impulse is applied from the board of an aircraft to an electric igniter of a cartridge held in the holder’s cassette by the bottom flange, a dense narrowly directed fire force is formed by means of a throttle nozzle, which enters into the ignition of the pyrotechnic composition of the functional bomb, which burns to generate an aerosol filling the receiver.

The increased pressure of the accumulated gaseous products of combustion, which is distributed, is transmitted through the annular obturator to the checker and then to the lid. In this case, the lid with its longitudinal movement bends the petals of the sealed end, freeing up the passage for the checkers emitted into the atmosphere, where it burns down and creates an aerosol cloud of infrared radiation.

The source of infrared radiation is a red-hot solid phase of the aerosol, which forms a false target for means of detecting and guiding the enemy.

However, this pyrotechnic cartridge is characterized by the following disadvantages.

In the throttling nozzle of the holder, in which the electric igniter is mounted, a fire force is dynamically formed, which reliably ignites the pyrotechnic checker, but at the same time (especially on small calibers), cases of its destruction are possible, which arbitrarily changes the mode of combustion and throwing of the cartridge's useful filling, the volume of the masking cloud decreases , reducing the effectiveness of the intended action, the combat mission is not performed in a given volume.

In addition, soot, which inevitably forms during the burning of the pyrotechnic composition of the functional checker, settles on the contact elements inside the shell of the electric igniter (central current lead and upper disk electrode), electrically closing them, which simulates an incandescent bridge that has already burned out.

As a result of this, a false signal appears on the display of the launch device of the aircraft indicating that the cartridge is ready to be put into operation.

The protection of the aircraft in the form of setting a false target is not realized at the same time, which is unacceptable in the conditions of military operations.

The problem to which the present invention is directed, is to increase the functional reliability of the jamming cartridge.

The required technical result is achieved by the fact that in the well-known pyrotechnic cartridge of infrared radiation, in the sleeve of which a functional checker is installed, closed by a lid resting on a shell forming a receiver above an electric igniter device interacting with the terminals of the cassette holder on the aircraft fuselage by means of mounted in a mounting block made in the form of a sleeve flange, a central current lead and separated by a non-conductive gasket of the lower and upper electrodes, pos the ice of which is connected by an incandescent bridge with a central current lead equipped with an obturating flange and closed to the housing, while the incandescent bridge is placed in the initiating charge of the cap, the output window of which is directed towards the checker, according to the invention, the functional checker is mounted on a mesh diaphragm that separates it from the receiver , the exit window of the cap with the initiating charge is covered by a gas-permeable membrane, and the lower ring electrode is mounted on the contact surface of the flange, coaxially centered the current lead, and by means of a load resistor, is connected to its obturating flange isolated from the upper disk electrode, while the gas-permeable membrane of the output window of the electric igniter is made in the form of a mesh casing mounted on the cap, the flange of which is filled with a compound layer in the gap between the transverse pressure cap of the cap and sealed on it by the end face of the shell.

Distinctive features mechanically prevented the false circuit of the spent cartridge electrical circuit in its three-electrode electric igniter with separate connection in the control and operation modes, which provides increased functional reliability for the noise protection of aircraft, due to routine checks of internal electrical circuits before their intended use.

In this case, the active integrity control of the electrical circuits of the means for initiating interfering munitions is carried out directly from the aircraft before firing, in the standby mode of the reference voltage.

The installation of a functional checker on a gas-permeable mesh diaphragm, firstly, protects it from the destructive action of a highly directional fire torch formed by the initiating charge of the electric igniter, and secondly, eliminates the sedimentation of soot into the receiver and, therefore, inside the shell of the activated electric igniter.

A gas-permeable membrane is directly aimed at this, directly blocking the exit window of the cap of the electric igniter, which serves as the second stage of protection against unauthorized closing of its contacts, in which a false signal is generated on the control panel display about the readiness to start the cartridge that has already worked.

The fastening of the flange of the mesh casing mounted on the cap of the electric igniter (as the mesh membrane of the exit window) to the transverse overlay by means of a compound layer, which is poured under the rolling end of the shell, ensured a monolithic barrier preventing the breakdown of hot products of combustion of the functional checker to the fuselage of the aircraft.

The implementation of the lower disk electrode in the form of a ring mounted on the contact surface of the coaxially obturating flange of the central current lead forms an additional contact of alternative connection of the electric igniter to the current source, which extends the technological capabilities of the product.

Connecting the lower disk electrode to the central current lead through a load resistor, the electrical resistance of which is two orders of magnitude higher than the electrical resistance of the incandescent bridge, allows you to regularly ring the entire circuit of the device, guaranteed to exclude the incandescence of the bridge.

The mechanical separation of the upper disk electrode and the obturating flange with a non-conductive gasket ensures their electrical connection only through the central current lead, which is necessary for the independent supply of operating current directly to the incandescent bridge.

Overlapping the outlet opening of the cap with an igniting charge of a gas-permeable diaphragm is necessary to prevent the electrical circuit of the incandescent bridge by sediment soot after burning ammunition equipment, which eliminates the false signal on the control panel about the readiness of the triggered electric igniter for shooting.

The implementation of the diaphragm in the form of a grid of heat-resistant material ensures the permeability of the flame force during combustion of the igniter composition and prevents soot particles from entering the cap of the electric igniter, which, ultimately, increases the safety of the aircraft when setting a false target or camouflage cloud.

An additional technical effect of expanding technological capabilities lies in the fact that the proposed design makes it possible to identify cartridges of various functions in the launching device on board an aircraft by type of payload: anti-radar dipole reflectors, infrared smoke screen, etc.

This is achieved by using load resistors of different nominal ohmic resistance in the ignitor circuit, which form a different level of controlled output current, each of which is inherent in a particular type of product.

Therefore, each essential feature is necessary, and their combination in a stable relationship is sufficient to achieve a novelty of quality that is not inherent in the characteristics of disunity, that is, the stated technical problem is solved not by the sum of the effects, but by a new super-effect of the sum of the attributes.

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 it is not known, and taking into account the possibility of industrial serial production of anti-radar cartridges and infrared cartridges, it can be concluded that it matches patentability criteria.

The essence of the proposed invention is illustrated by drawings, which have purely illustrative purposes and do not limit the scope of the claims of the formula. The drawings show:

figure 1 - interference-generating cartridge of infrared radiation;

figure 2 is a General view of the electric igniter, a longitudinal section;

figure 3 is a view of 1 in figure 2;

figure 4 is a section along aa in figure 2;

figure 5 is a diagram of the electrical connection of the electrodes.

The proposed infrared radiation cartridge contains (FIG. 1) a pyrotechnic checker 2 mounted coaxially in the aluminum body 1 and an electric igniter 3 mounted in the bottom flange 4 of the body 1, for which the cartridge is held in the cassette holder on the aircraft fuselage.

The checker 2 rests on the shell 5 forming the receiver 6 above the output nozzle 7 of the electric igniter 3.

Between the checker 2 and the casing 5 is a mesh diaphragm 8 made of stainless steel.

The checker 2 is closed from above by a sealing cover 9, sealed with the material of the open end of the housing 1, ensuring their power and geometric closure in official use.

The checker 2 is equipped with longitudinal fire-transfer channels 10 for spreading a heat pulse to its side surface, thereby increasing the burning surface of the checker 2 and the intensity of the generation of functional aerosol.

The electric igniter 3 contains (FIG. 2) an igniter charge 12 placed in the cap 11, inside which an incandescent bridge 13 is placed, electrically connected (FIGS. 2 and 3) with a central current lead 14 and an upper disk electrode 15 mounted on a non-conductive gasket 16.

The cap 11 having an outlet 17 (Fig. 2) is adjacent to the upper disk electrode 15 by means of a transverse lining 18, which is loaded from above by rolling the open end of the shell 19, which ensures their electrical contact with geometric and power closure.

The coaxial nozzle 7 of the flange 4 of the housing 1, the outlet 17 of the cap 11 is closed by a stainless steel mesh diaphragm 20, which is mounted in the form of a congruent casing on the cap 11. The mesh casing flange is filled with a layer of sealant 21 filling the gap between the rolling of the open end of the shell 19 and the supporting surface of the lining 18, while the sealant of the layer 21 monolithically glues the mesh of the diaphragm 20 to the carrier strip 18.

The heat-resistant material of the alloy steel mesh 20 is resistant to the combustion temperature of the igniter charge 12.

Soot particles, which inevitably form when burning any functional composition of ammunition equipment, settle on the diaphragm grid 20 and do not penetrate the cap 11. This eliminates the possibility of unauthorized closing of the gap between the central current lead 14 and the upper disk electrode 15, which electrically simulates the signal on the control panel display from the filament bridge 13, which actually burned down, which is typical of the prototype.

In this case, a false triggering of the fired cartridge may occur, which will not perform the function of setting aerosol interference to protect the aircraft, which is unacceptable.

The Central current lead 14 is equipped with an obturating flange 22, which is installed in the mounting block 23 of electrical insulation material.

The upper disk electrode 15 from the obturating flange 22 of the Central current input 14 is separated by a non-conductive gasket 24.

An annular lower electrode 24 is fixed to the contact end of the block 23 coaxially to the central current lead 14, which is rigidly connected through rivets 25 through a bus 26 with a load resistor 27 connected through a obturating flange 22 to the central current lead 14 (Figs. 2 and 4).

Thus, a three-electrode circuit (Fig. 5) of an electric igniter 3 is formed consisting of serially connected: the lower ring electrode 25 - the central current lead 14 - the upper disk electrode 15 attached to the housing shell 19, while the lower disk electrode 25 and the central current lead 14 are connected through the load resistor 27, and the central current lead 14 and the upper disk electrode 15 through the glow bridge 13.

A feature of this three-electrode circuit of the electric igniter 3 is that the electrical resistance of the circuit section between the lower ring electrode 25 and the central current lead 14 is significantly (100 times) greater than the electric resistance of the circuit section between the central current lead 14 and the upper disk electrode 15, namely: the resistance of the load resistor 25 is 200 ohms, and the electrical resistance of the filament bridge 13 is 2 ohms.

This allows you to carry out routine verification of the integrity of the electrical circuit of the electric igniter 3 mounted in the ammunition by applying to the lower electrode 25 and the shell 19 a reference voltage U _op , the drop of which occurs on the load resistor 27, and the current flowing through the glow bridge 13 is much lower than the level required to warm to melting point.

However, at the same time, a signal is generated on the display of the control unit on board the aircraft, indicating the integrity of the circuit of the igniter 3 and the functional readiness of the cartridge as a whole.

Structurally, the communication circuit of the functional elements consists of two circuits connected in series:

lower ring electrode 25 - load resistor 27 - obturation flange 22 - central current lead 14 - glow bridge 13 - upper disk electrode 15 - shell 19 (for routine inspection);

central current lead 14 - glow bridge 13 - upper disk electrode 15 - sheath 19 (for operating voltage).

The pyrotechnic cartridge operates as follows.

When you press the "Start" button on the control panel in the cockpit of the aircraft, the operating voltage U _p is supplied to the central current lead 14 of the electric igniter 3 (Fig. 5) and through the case shell 19 to the upper disk electrode 15, as a result of which a potential difference appears on the glow bridge 13 with the release of heat, which ignites the heat-sensitive composition of the charge 12 in the shell 11 (figure 2).

The force of hot gaseous combustion products of charge 12 through the mesh diaphragm 20 of the outlet 17 of the shell 14 and the focusing nozzle 7 of the flange 4 of the cartridge case 1 (Fig. 1) enters the functional block 2, igniting it from the end and through the channels 10 along its perimeter.

At the same time, the sealant layer 21 and the obturating flange 22 (Fig. 2) of the central current lead 14 adjacent to the ledge of the block 23 reflect the hot gaseous products of combustion of the igniter charge 12 and pyrotechnic checkers 2, preventing them from breaking through to the cassette holder on board the aircraft.

When burning the pyrotechnic composition of the checkers 2, an aerosol is generated, in particular, infrared radiation of the condensed phase.

The aerosol penetrates through the heat-resistant mesh of the membrane 8 and fills the volume of the receiver 6.

The increased pressure of the gaseous products of combustion of the checkers 2 in the receiver 6, the cover 9 is knocked out of the fold-back rolling of the open end of the housing 1.

Further, the functional aerosol flows freely into the atmosphere, where it forms a false target for detection and guidance in the form of a cloud simulating the working engines of an aircraft, by means of infrared radiation in the near frequency spectrum of the range.

The precipitating soot, which is formed by burning the pyrotechnic composition of the checker 2, is delayed on the grids of the membrane 8 and the diaphragm 20, guaranteed not to get into the cap 11 of the activated electric igniter 3.

The proposed technical solution allows you to expand the functionality of the launch device of the aircraft by identifying different types of cartridges with different fillings before setting up the target launch due to the installation of 27 discrete nominal load resistors in them, for example, 150 Ohms, 200 Ohms, 250 Ohms, getting different level signals on the display of the starting device.

So automatically, by supplying the reference voltage when the internal electric circuits of the electric igniter 3 sound, the location of the homogeneous cartridges in the cassette holder is fixed in the start channels.

Thus, the proposed technical solution expands the technological capabilities and increases the functional reliability of the cartridges of the target action, which ultimately increases the survivability of aircraft due to the mobile setting of the necessary protection from enemy detection and guidance.

Bench tests of prototypes of the proposed pyrotechnic cartridge with a modernized design of an electric igniter confirmed the feasibility of its serial implementation for the protective equipment of aircraft.

Claims (2)

1. Pyrotechnic infrared radiation cartridge for an aircraft, in the sleeve of which a functional checker is installed, closed by a lid and resting on a shell forming a receiver above an electric igniter device, interacting with the cassette holder terminals on the aircraft fuselage by means of a sleeve mounted in a mounting block made in the form of a sleeve flange , the central current lead and separated by a non-conductive gasket of the lower and upper electrodes, the last of which is heated by a bridge I am electrically connected to a central current lead equipped with an obturating flange and closed to the housing, while the incandescent bridge is placed in the initiating charge of the cap, the output window of which is directed towards the checker, characterized in that the functional checker is mounted on the mesh diaphragm that separates it from the receiver, the output the cap window with the initiating charge is covered by a gas-permeable membrane, and the lower ring electrode is mounted on the contact surface of the flange coaxially with the central current lead and by means of heating a narrow resistor is connected to its obturating flange isolated from the upper disk electrode. 2. The pyrotechnic cartridge according to claim 1, characterized in that the gas-permeable membrane of the outlet window of the electric igniter is made in the form of a mesh casing mounted on the cap, the flange of which is filled with a layer of compound in the gap between the transverse pressure cap of the cap and the shell end rolled on it.

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