RU143883U1 - DEVICE FOR INSTALLING RADAR INTERFERENCE - Google Patents

Abstract

1. A device for setting anti-radar jamming, comprising rigidly connected to a cylindrical body, inside which are placed a multitude of functional modules of the payload, a jet engine, a radial rotation mechanism, initiating means installed in a head cover resting on a disk support and communicating by means of a retardation sleeve with an energy-saturated mechanism for ejecting modules, and a rupture mechanism, characterized in that the jet engine is located under the spring loaded head roof a housing connected by pyro-bolts, the nozzles inclined to the longitudinal axis of which are installed in the disk support and are communicated by the receiver’s communication channel with a ring solid-fuel block of a jet engine, and the energy-saturated charge of the module ejection mechanism, made in the form of a gas-generating pyrotechnic block, is installed in a piston supported by functional modules placed in the technological compartment mounted on a jet engine with a guaranteed annular gap relative to the coaxial housing, sn abzhennogo mounting bandage. 2. The device according to claim 1, characterized in that the functional modules of the payload are made in the form of inflatable reflectors made of polymer material, in the form of flat sealed containers.

Description

The utility model relates to the field of protection of aircraft from radar detection means by creating in the atmosphere a screen from a discrete set of formations reflecting electromagnetic radiation.

The level of this technical field is characterized by the projectile described in US patent No. 5040465, F42B 12/70 (102/505), 1977, including rigidly connected fairing, head and jet engine.

An ignition system is installed in the fairing, and a payload is provided in the head part, as well as a mechanism for destroying the shell of the head part moving by the piston under the pressure of the combustion gases of the ignition system and expelling charge, structurally connected to the first protective disk, and a payload ejection mechanism including a second protective a disk and an ejection charge connected by an axial channel to a transmitting charge.

The piston contains in front of the radial holes with springs.

The payload is distributed in individual sectors of the multicellular cylinder, which are located around the axial channel, have recesses at the front ends for ejection by an oncoming air stream and are joined by cylindrical outer walls.

When the engine starts, the timer starts, after a certain delay the ignition system in the cowl ignites the expelling charge. Gases from it penetrate through the holes in the disk and act on the piston, forcing it to move toward the jet engine.

At the same time, the piston discharges the shell of the warhead with the firing pin removed, the buoyant charge from the transmitting charge through the axial channel is triggered.

Further, the springs are activated, throwing sectors into the atmosphere, where they open, forming a cloud of dipole interference.

This projectile with precision precision structural mechanisms and pyro-gunpowder actuators is practically used in the US Army for its intended purpose.

However, the disadvantages of the described anti-radar projectile are as follows.

The poor protection efficiency of the aircraft due to the impossibility of scattering the payload at a sufficient distance in the radial direction, since the sectors of the multi-cell cylinder after being ejected from the projectile do not form a single whole and randomly scatter, which leads to passive and disorganized dispersion of the functional content.

In this case, the longitudinal size of the generated interference cloud is limited by the fact that the ejection of the payload from the projectile forward along the flight path is by definition impossible to a large distance during aerodynamic deceleration of the sectors that are scattered near the projectile.

More perfect is a turbojet radar jammer according to patent RU 2422759 C2, F42B 12/70, 2003, which is selected according to the technical nature and the number of matching features as the closest analogue to the proposed device.

Known projectile, made with the possibility of axial rotation, includes a rigidly connected longitudinally turbojet engine and the head with a payload laid in a cylindrical body, and a fuse (initiating means) in the head cover.

The initiating means communicates with an igniter charge on the disk support and a rupture mechanism, including an explosive charge, placed in a cup with a throttle communication channel.

The head part is made with the axial channel of the igniter charge message with propellant charge forward of the functional modules made with axial eccentricity, contributing to radial expansion.

The payload is made in the form of dipole reflectors placed in the cavity of the disk modules, in many stacked on top of each other.

During the operation of a known projectile in a short period of time, a dense masking cloud forms over the protected object.

The execution of a rocket by rotating and each of the disk modules with its own axial eccentricity stimulates the ejection of modules from the housing over a considerable distance due to the action of powerful axial and centrifugal forces on them.

Laying the payload in the disk modules, mainly in the form of biscuits, ensures the safety of dipole reflectors before they are scattered, and the scattering mechanism ensures the required setting time and the size of the generated interference cloud.

The design of each module of the mechanism of dispersion of the payload simplifies the ejection of the payload from the cavity of the module without destroying it.

The implementation of the mechanism of ejection of the payload installed in the head part in the form of an ejection charge, additionally equipped with pyro-retarders, ensures that all disk modules with the payload are guaranteed to be thrown forward along the path of the projectile from the projectile at a specified time, which increases the efficiency of the main action.

The pyrotechnic connection of the buoyant charge with the ignition charge through the through axial channel provides instant transmission of the force of fire and the operation of the ejection mechanism of the payload.

A feature of the known projectile is that the ignition system installed in the initiation means (head fuse) and the destruction mechanism of the body of the head part and the ejection of the payload are structurally connected and contain sequentially set ignition, separation and knocking charges.

This ensures a reliable connection of the elements of the mechanism, its operation from the force of the initiating fire, the destruction of the body of the head and the free release of the payload.

However, a continuation of the advantages of the known device are inherent disadvantages.

The main disadvantage is the narrow-purpose designation for the dispersion of dipole reflectors from throwable biscuits ejected from functional modules, and the unsuitability by definition for shielding from polymer inflatable reflectors due to direct contact with its pyro-powder actuators.

In addition, a significant part of the energy-containing charges of the actuating elements is spent on the destruction of structural parts, which reduces the propelling momentum of dispersion of functional modules.

In this case, the longitudinal arrangement with the sequential placement of the head part, in the body of which the payload is laid, and the jet engine further reduces the fill factor and the efficiency of the device for the intended purpose.

The technical problem to which the present utility model is directed is to expand technological capabilities and increase the efficiency of the compact coaxial arrangement, more functional and reliable.

The required technical result is achieved by the fact that in the known device for setting anti-radar jamming, which is rigidly connected to a cylindrical body, inside of which are packed functional modules of a payload, a jet engine, a radial rotation mechanism, initiating means installed in a head cover resting on a disk support, and communicating by means of a retarding sleeve with an energy-saturated mechanism for ejecting modules, and a rupture mechanism, at the suggestion of the authors, the reaction The live engine is placed under the spring-loaded head cover of the housing, connected by pyro-bolts, the nozzles inclined to the longitudinal axis of which are installed in the disk support and communicated by the receiver's communication channel with the solid-propellant ring checker of the jet engine, and the energy-saturated charge of the module ejection mechanism, made in the form of a gas-generating pyrotechnic checker installed in a piston supported by functional modules placed in a technological compartment mounted on a jet engine with a guarantee with an annular gap relative to the coaxial housing provided with a mounting brace, while the functional modules of the payload are made in the form of inflatable reflectors made of polymer material, in the form of flat sealed containers.

Distinctive features of the proposed technical solution provided automatic sequential operation of the destruction mechanism of the structural unity of the elements, the launch of a jet engine and the mechanism of ejection of the payload, excluding direct contact of the shock load on the reflecting elements.

In this case, correspondingly, the head cover is separated and discarded from the housing fixed on the carrier for passage formed from a technological compartment carrying a plurality of functional modules and a monoblock reactive drive, as well as the movement of a piston equipped with a gas-dynamic drive, in the opposite direction, pushed out of the technological compartment into atmosphere of inflatable reflectors of electromagnetic radiation.

Known radio interference reflectors made of thin elastic material are transformed from a flat shape of sealed containers compactly stacked in a stand-alone compartment for transportation and storage, into pressurized inside from excess pressure from a gas generator (see, for example, US Pat. No. 3,115631, No. 3169725 and No. 4166597 , France No. 2547474, F41H 9/00, as well as Velikanov VD et al. "Radio engineering systems in rocket technology, M., Military Publishing House, 1974 and Bail-Amer. Met. Soe, 1969, v. 50, No. 11 , p. 867-874 ")

The placement of the jet engine under the head cover of a stationary mounted housing is aimed at autonomous longitudinal movement of the technological compartment, rigidly connected to the jet engine carrying functional modules, during its operation.

A rigid connection of the housing with the head cover by means of pyro-bolts ensures the monolithicity of the structural elements of the device in official circulation, existing as a self-sufficient product, and their guaranteed mechanical separation at a given operation of the pyro-bolts for autonomous functioning.

The loading of the head cover with elastic springs is necessary for its automatic separation from the housing after pyro-bolt operation, in order to free up the passage for the disk support carrying the structural elements of the device.

The rigid connection of the jet engine with the disk support and on the opposite side - with the technological compartment forms a monoblock mounted with the possibility of longitudinal movement relative to the bearing body.

The nozzle mount tilted to the longitudinal axis of the jet engine creates a torque for gyroscopic stabilization of the autonomous jet propulsion of the monoblock, including a technological compartment with a payload.

Message nozzles through the communication channel of the receiver, made in a disk support, with a solid-fuel checker of a jet engine forms a path for the jet ejection of the generated working fluid, creating a traction force of movement of the monoblock relative to the stationary housing.

The charge of the module ejection mechanism in the form of a pyrotechnic block, during combustion generating gaseous products in a limited volume of its placement, provides a sharp increase in pressure, under the action of which the piston moves along the technological compartment and pushes the functional modules in front of it, opposite to the movement of the monoblock.

A coaxial installation with a guaranteed annular gap in a stationary housing of a technological compartment mounted on a jet engine is necessary for its relative free movement during operation of the device.

The hull is equipped with a mounting brace for mounting in an aircraft.

The implementation of functional modules in the form of flat sealed containers made of a polymeric material ensures their automatic inflation by the air contained inside when they are emitted into the discharged atmosphere, forming a lot of random volumetric reflectors of electromagnetic radiation waves during aircraft radar.

Consequently, 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 technical task posed is not solved by the sum of the effects, but by a new super-effect of the sum of the attributes.

The essence of the proposed utility model is illustrated by the drawing, which has a purely illustrative purpose and does not limit the scope of claims of the totality of the essential features of the formula. The drawing shows a device for setting anti-radar interference.

The cylindrical body 1 of the device, equipped with a mounting band 2 for mounting in the carrier, is closed by a head cover 3, which is loaded with springs 4.

The head cover 3 by means of pyro-bolts 5 is rigidly connected in official circulation and during operation of the aircraft with the body 1, forming an autonomous capsule in which the structural elements of the device are isolated.

An axial electric igniter 6 is mounted in the lid 3, which is connected similarly to pyro-bolts 5 with an external starting device on board the aircraft and communicating at the outlet with the throttling sleeve 7.

The head cover 3 is adjacent to the disk support 8, on which a jet engine 9 is mounted with distributed nozzles 10 inclined to the longitudinal axis of the engine 9.

The nozzles 10 communicate through the switching channel 11 of the receiver 12 with the ring solid propellant checker 13 of the jet engine 9.

Coaxial to the electric igniter 6, a slowdown sleeve 14 is installed, which is directly connected to the gas generating charge 15 mounted in the piston 16 adjacent to the engine 9 and installed with the possibility of longitudinal movement inside the technological compartment 17 with a payload in the form of a series of inflatable reflectors 18.

Reflectors 18 are made of polymeric material in the form of flat sealed containers.

The technological compartment 17 below (according to the drawing) is closed by a removable cover 19 and in the coaxial housing 1 is located with a guaranteed annular gap 20, which allows free longitudinal movement relative to the housing 1.

The proposed device operates as follows

When a command is issued from the side of the aircraft, pyro bolts 5 and an axial igniter 6 are triggered, as a result of which the mechanical connection of the head cover 3 with the housing 1 is broken and a sharply directed fire force is formed in the throttle sleeve 7, respectively.

Under the action of the elastic energy of the springs 4, the head cover 3 is thrown away from the housing 1, opening the passage for the disk support 8 with a jet engine 9 and the technological compartment 17 (monolithic design of autonomous movement).

The solid fuel squeezed in the sleeve 7 ignites a solid propellant bomb 13, during combustion of which gaseous products are formed along the developed surface, passing through the channel 11 to the receiver 12, where they accumulate, mix and are thrown out with pressure through the nozzles 10, creating a thrust.

Under the influence of traction, the disk support 8 together with the jet engine 9 and the technological compartment 17 move longitudinally relative to the stationary housing 1, radially rotating, since the jet of nozzles 10 are inclined relative to the longitudinal axis of the engine 9 and generate torque for gyroscopic stabilization of the structure in autonomous flight .

The design 8-9-17 in flight is longitudinally stabilized aerodynamically due to the displacement of the center of mass forward relative to the center of pressure.

After a predetermined delay time, determined by the geometry of the axial channel of the retarder sleeve 14, the payload 15 of the payload ejection from the compartment 17 is ignited, which generates a large volume of gas during combustion - the working fluid of the piston 16.

Under the distributed load of the piston 16, the lower cover 19 collides with the compartment 17 and, through its open end, reflective containers 18 are ejected piecewise into the atmosphere.

At the same time, sealed containers 18 are inflated in a discharged atmosphere under the influence of residual air inside, forming volume reflectors, many of which create an arbitrary set of discrete reflectors around the aircraft. The spatial combination and mutual relation of inflatable reflectors in the atmosphere is constantly changing.

The overall contour of the aircraft by the number of inflatable reflectors 18 surrounding the atmosphere is fragmented and distorted, therefore, it is not identified with a given profile in enemy detection means.

Comparison of the proposed technical solution with the identified analogues of the prior art did not reveal an identical match of the set of essential features for the utility model.

The proposed differences of the device for setting anti-radar interference are not obvious to a specialist in automation, which directly follow from the statement of the technical problem.

The manufacture of a set of structural elements of the device in their interconnection can be carried out at the existing production, where stand-alone analog devices are manufactured according to the existing technology.

From the foregoing, it can be concluded that the options for a utility model correspond to patentability conditions.

Claims (2)

1. A device for setting anti-radar jamming, comprising rigidly connected to a cylindrical body, inside which are placed a multitude of functional modules of the payload, a jet engine, a radial rotation mechanism, initiating means installed in a head cover resting on a disk support and communicating by means of a retardation sleeve with an energy-saturated mechanism for ejecting modules, and a rupture mechanism, characterized in that the jet engine is located under the spring loaded head roof a housing connected by pyro-bolts, the nozzles inclined to the longitudinal axis of which are installed in the disk support and are communicated by the receiver’s communication channel with a ring solid-fuel block of a jet engine, and the energy-saturated charge of the module ejection mechanism, made in the form of a gas-generating pyrotechnic block, is installed in a piston supported by functional modules placed in the technological compartment mounted on a jet engine with a guaranteed annular gap relative to the coaxial housing, sn abzhennogo mounting bandage. 2. The device according to p. 1, characterized in that the functional modules of the payload are made in the form of inflatable reflectors made of polymer material, in the form of flat sealed containers.