RU2340860C1 - Missile for active impact on clouds - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: invention concerns devices for change of atmospheric conditions, in particular to solid fuel rockets for active influence on clouds. The rocket contains a receiver located between the amplifier of the firing impulse and the electrocapsular plug, a nozzle block with central electrocapsular plug, two longitudinal located channel powder draughts established with radial backlashes concerning the case, the amplifier of the firing impulse, a transfer pyrotechnic charge in the form of the cumulative funnel adjoining to the nozzle, executed in a kind of decelerator from the pyrotechnic structure which time of burning exceeds time of burning of channel powder draughts, and a channel draught of an active smoke. The powder draughts are executed with the equal arches of burning, divided by a diaphragm and established in the general case. The relation of sizes of a radial backlash between the case and channel powder draughts inversely proportional to the relation of diameters of channels of the mentioned draughts, and lengths L₁, L₂ the mentioned draughts are defined from following parities:

and

where

- criterion of Pobedonostsev. Simplification of a design of the jet engine at increase of its functional reliability and more effective influence of a rocket on clouds is provided.

EFFECT: simplification of a design of the jet engine at increase of its functional reliability and more effective influence of a rocket on clouds.

2 dwg

Description

The invention relates to devices for changing atmospheric conditions by dispersing aerosol generated during the combustion of a pyrotechnic checker in the clouds, and more particularly, to a solid propellant engine of meteorological rockets for active impact on the clouds.

The level of this technical field characterizes the patent RU 2110040, F42B 12/36, 1998, selected as the closest analogue, which describes a rocket for active exposure to clouds with a solid propellant jet engine.

One of the functional elements of this rocket is a solid-fuel dual-mode engine containing a nozzle block and two housings rigidly connected by an adapter, each of which includes a channel-mounted powder gun and a pyrotechnic gun to stabilize its combustion, as well as an amplification charge.

Powder blocks are mounted on gas-dynamic gratings, with the lower grate resting on the nozzle block and the upper grating on a bearing adapter between two engine housings.

In the nozzle block, a central electrocapsule sleeve is installed, connected with the power supply of the launcher.

The amplifying charge of the housing adjacent to the nozzle block serves as an igniter for the second-mode channel powder bomb, the amplifying charge of which acts as a device for initiating combustion of the channel bomb of active smoke located in the head of the rocket.

The described design is used in the Alazan-6 meteorological rocket as a jet engine with sections: starting and marching modes.

The practice of manufacturing and operating a well-known rocket has shown a number of inherent disadvantages of this engine.

The structural complexity of the dual-mode engine determines the technological problems of manufacturing a sectional casing with autonomous pyrotechnic, powder checkers and sequential transfer gears, which increases labor costs.

With the sequential operation of the engine sections in the starting and marching modes, the increase in traction characteristics to maximum values is stretched in time, which makes the rocket sensitive to surface winds, significantly affecting the accuracy of firing, deviating the flight path from the given one.

The use of additional pyrotechnic checkers in each engine section, stabilizing the combustion of the main channel powder checkers, and the associated need for the use of amplifying charges for sequential transfer of the ignition pulse, reduces the payload and reduces the rocket's traction characteristics.

A shorter flight distance limits the effective use of active aerosol directly in the cloud remote from the firing position.

The problem to which the present invention is directed, is to increase the functional reliability of a solid rocket engine to ensure stability at launch and in flight, while increasing the effectiveness of the missile for its intended purpose.

и

где

- критерий Победоносцева, а передаточный пиротехнический заряд выполнен в виде замедлителя из пиротехнического состава, время горения которого в кратное число раз больше времени горения канальных пороховых шашек двигателя, причем устройство инициирования канальной шашки активного дыма размещено на дюзе, а торец передаточного пиротехнического заряда, обращенный к устройству инициирования канальной шашки активного дыма, выполнен в виде кумулятивной воронки, примыкающей к дюзе.The required technical result is achieved in that in a known rocket for active exposure to clouds containing a nozzle block with a central electrocapsule sleeve, two longitudinally arranged channel powder bombs installed with radial clearances relative to the housing, an igniter pulse amplifier, a transfer pyrotechnic charge and a channel smoke bomb with a device for its initiation, located in the head of the rocket, according to the invention it is equipped with a receiver located between divisor of igniting pulse and elektrokapsyulnoy sleeve channel gunpowder checkers formed with equal arches combustion, separated by a diaphragm and are mounted in a common housing, wherein the ratio of the radial gap t ₁ between the housing and the lower channel propellant checker and size similar clearance t ₂ the upper channel propellant checkers back in proportion to the ratio of the diameters of the channels of said checkers, the lengths L ₁ , L _{2 of} said checkers are determined from the following ratios:

and

Where

- Pobedonostsev’s criterion, and the transfer pyrotechnic charge is made in the form of a moderator of the pyrotechnic composition, the burning time of which is several times longer than the burning time of the channel powder bombs of the engine, and the device for initiating the channel bombs of active smoke is placed on the nozzle, and the end of the transfer pyrotechnic charge facing a device for initiating a channel checker of active smoke, made in the form of a cumulative funnel adjacent to the nozzle.

Distinctive features provided a simplified design of the jet engine, characterized by a more dynamic launch mode and a stable flight mode, and increased its functional reliability for more effective impact of the rocket on the clouds with active smoke generated directly at the target.

Equipping the rocket engine with a receiver ensures that the peak pressure of the burning start of the powder bombs is smoothed out at start-up and, therefore, reduces the dynamic load on the load-bearing elements of the nozzle block by several times, and also acts as a diffuser on the march, where the dynamic characteristics of the flow, pressure and velocity of the combustion gases before feeding into the nozzle block.

Placing an igniter pulse amplifier and an electric ignition bush in the receiver engine significantly reduces the peak pressure of the gaseous products of combustion at start up to a level at which there is no destruction of the nozzle block and there is no need for its mechanical amplification with a concomitant increase in ballast mass.

The installation of the igniter coaxially, through the receiver, to the electrocapsule sleeve makes it possible to perceive its initiating fire pulse on the launcher for simultaneous ignition through the coaxial central channels of both powder bombs located on the common diaphragm, the combustion of which occurs synchronously over the entire surface in a stable mode.

This made it possible to exclude pyrotechnic checkers, stabilizing the combustion of channel powder checkers, and an amplifying charge of sequential switching on the flight of the second engine operating mode according to the prototype. Due to the released volume, the mass of powder checkers and, consequently, the traction characteristics of the engine are increased.

Simultaneously with the ignition of the powder bombs by a heat pulse transmitted through their axial channels, combustion of the pyrotechnic composition of the moderator is automatically initiated from the common igniter device.

An equal burning set of both channel powder guns mounted in a common housing provides a stationary engine operating mode, which gives a more dynamic descent of the rocket from the launcher, having an increased initial speed to eliminate the negative impact on the accuracy of the surface winds.

Performing a radial clearance between the housing and the channel powder checker adjacent to the nozzle block, larger than the similar clearance of the installation of the second upper checker, in a ratio inversely proportional to the ratio of the diameters of their channels, ensures the stability of the gas-dynamic mode of operation of the engine throughout its operation. The smaller radial clearance between the casing and the checker from the nozzle block side accelerates the peripheral flows of the combustion products of both pieces, the volume of which significantly exceeds the central stream through the axial channels, which increases the thrust.

To ensure identical gas-dynamic conditions for the flow of generated gaseous products of combustion through passage sections of both channel powder blocks in a stationary jet engine, the length of the blocks functioning together in a common casing is selected from the following ratios:

и

and

where L ₁ is the length of the channel checkers adjacent to the nozzle block;

L ₂ - the length of the upper channel pieces;

- критерий Победоносцева;

- Pobedonostsev criterion;

t ₁ is the radial clearance between the housing and the checker adjacent to the nozzle block;

t ₂ - radial clearance of the upper channel pieces.

The implementation of the transfer pyrotechnic charge in the form of a moderator of the pyrotechnic composition, the burning time of which is several times longer than the burning time of the channel powder bombs of the engine, provides a time delay in the initiation of the bombs of active smoke, that is, the beginning of the generation of working aerosol.

During this delay, the rocket inertia (after the engine is finished) reaches the cloud being treated, which ensures a more rational use of the working aerosol with active particles directly in the cloud.

The generated aerosol additionally flows out through the nozzle block in the form of larger condensed particles when moving along the free volume of the engine housing.

Additional fractionation of aerosol particles of active smoke increases the efficiency of exposure to clouds, in particular, acting as centers of condensation of atmospheric moisture for precipitation.

Placing the device for initiating pyrotechnic pieces of active smoke on the nozzle focuses the fire force, as the nozzle acts as a lens.

The execution of the end of the transfer pyrotechnic charge, facing the device for initiating ignition of the channel blocks of active smoke, in the form of a cumulative funnel adjacent to the nozzle, increases the functional reliability of the fire chain by focusing hot combustion products in a sharply directed force.

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

The invention is illustrated by drawings, where in Fig.1 schematically shows a meteorological rocket with the proposed jet solid propellant engine, in Fig.2 - the head of the rocket.

The meteorological rocket contains a head part 1, closed by an aerodynamic fairing 2, a jet engine 3 with two channel powder checkers 4, 5, coaxially sequentially mounted in a common housing 6, and an ignition pulse amplifier 7, located coaxially with the central electrocapsule sleeve 8 of the nozzle block 9 equipped with a blade stabilizer 10.

The amplifier 7 of the ignition pulse from the electroflamer sleeve 8 is installed in the lattice 11, resting on the end protrusion of the nozzle block 9, a shaping receiver 12 for diffusion expansion of the gas stream from the combustion chamber of the powder bombs 4, 5.

Channel powder checkers 4 and 5 of the engine 3, having an equal combustion arch, are adjacent from different sides to the separation diaphragm 13 and are installed in the housing 6 with radial clearances 14 and 15 of 20 mm and 9 mm, respectively.

Thus, the total flow sections formed when installing the channel blocks 4 and 5 relative to the housing 6 are identically equal both in the static and in the dynamics of surface combustion of their equal arches.

Radial clearance 14 (t ₁₎ between the housing 6 and the channel checker powder 4 from the nozzle unit 9 exceeds a similar gap 15 (t ₂₎ installed in the upper housing 6 channel checkers powder 5 in a ratio inversely proportional to the ratio of their diameters channels.

In this case, the lengths L ₁ = 410 mm and L ₂ = 340 mm of the mentioned pieces 4 and 5 are determined from the following ratios, respectively:

- критерий Победоносцева (150).Where

- Pobedonostsev's criterion (150).

The housing 6 through the adapter 16 is connected with the head part 1, carrying channel pieces 17 of active smoke, which communicate with the device 18 for initiating their ignition installed in the adapter 16.

The device 18 is placed on the nozzle 19, adjacent to the top of the pyrotechnic moderator 20, based on the grate 21, separating from the channel powder checkers 5 of the engine 3.

The end face of the pyrotechnic transfer charge of the moderator 20, facing the device 18 for initiating ignition of the active smoke blocks 17, is made in the form of a cumulative funnel adjacent to the nozzle 19.

An exhaust manifold 22 is mounted between the body of the head part 1 and the fairing 2, in which a diffuser 23 which is distributed along the perimeter of the outlet openings 24, is arranged in the diffuser 23 in communication with the channel blocks of the active smoke.

In the diffuser 23 is located coaxial to the device 18 for initiating a nozzle 25 of the actuator 26 for self-liquidation of the rocket.

The actuator 26 sequentially includes a pyrotechnic moderator 27, two parallel interlocked beam detonator capsules 28 adjacent to the tape transverse explosive charge 29, shielded from above by a rigid reflective beam 30.

The tape charge 29 communicates with the longitudinal tape charges 31 located on the surface of the housings of the head part 1 and the engine 3 and the ring charge 32 of the explosive in the nozzle block 9.

Pyrotechnic moderator 27 of the actuator 26 of self-destruction at the ends is made with conical recesses 33 and 34, the lower and upper according to the drawing, respectively.

The lower recess 33, communicating with the nozzle 25, acts as a confuser to form a center-directed force from the incoming gaseous hot products.

The upper recess 34, directed towards the beam detonator capsules 28, is a cumulative funnel designed to concentrate the combustion products of the pyrotechnic composition of the moderator 27 into a dense heat flux.

Functioning rocket with the proposed jet engine as follows.

When the rocket is launched, electrical voltage is supplied to the electrocapsule sleeve 8, the ignition charge of which initiates an ignition charge 7.

The sharply directed torch of the activated amplifying charge 7 ignites the channel powder blocks 4, 5 and the pyrotechnic composition of the moderator 20. In this case, the blocks 4, 5 burn along the entire developed surface of the central channels and from the outside in radial clearances 14 and 15, and the moderator 20 burns at the end.

At the time of starting, the increase in pressure inside the engine 3 occurs rapidly in a jump and the powder gases rush to the nozzle block 9 to the exit. In the receiver 12 there is a deceleration of gas flows and smoothing of the peak pressure with a relatively smooth increase before feeding into the nozzle block 9.

Upon reaching the required thrust, the missile leaves the launcher on the flight path to the cloud being processed.

The means of communication of the solid-fuel engine 3 in the optimal ratio of geometric parameters: the central channels of the checkers 4, 5, radial clearances 14, 15, the grilles 11, 21 and the separation diaphragm 13, provide functional unity of the stable operation of the engine 3 in a stationary mode during the entire combustion cycle of the powder checkers 4 and 5.

The burning time of the moderator 20 is several times longer than the burning time of the channel powder blocks 17 of the engine 3 (10 s and 3 s, respectively), which makes it possible for the rocket to develop the maximum marching speed of the inertial movement to the target, after which the flat combustion front of the moderator 20 is a cumulative funnel of its end transforms into a torch, which is then focused with a nozzle 19, like a lens, to focus on igniting the pyrotechnic composition of the device 18.

The force of the flame from the initiating device 18 ignites the pyrotechnic composition of the channel blocks 17, during combustion of which an aerosol is generated (active smoke containing solid particles, which in the atmosphere of the cloud serve as droplet formation centers).

The generated aerosol enters the diffuser 23, where the gaseous products of combustion of the drafts 17 expand and with increased pressure are ejected through the distributed outlet openings 24 of the collector 22.

At the same time, the hot combustion products of the checkers 17, formed by the nozzle 25 and the confuser 33 into a concentrated torch, ignite the pyrotechnic composition of the moderator 27, the burning time of which is calculated to be guaranteed longer than the burning time of the checkers 17.

The generated aerosol during the burning of the checker 17 also spreads through the body 6 of the engine 3, which was free by then, and is ejected into the cloud through the nozzle block 9. When the aerosol moves along the engine 3, its active solid particles are agglomerated, so particles of different fractionalities and activity enter the treated cloud that more effectively intensifies the process of precipitation.

When the front of combustion of the pyrotechnic composition exits to the upper end of the moderator 27, the cumulative funnel 34 forms a fire torch, from which the detonator capsule 28 blocked in parallel is triggered.

The detonation wave from the detonator capsule 28 is directly transmitted to the adjacent tape charge 29 of the explosive, while being reflected from the shielding beam 30, preventing the destructive effect of the detonation wave on the fairing 2.

When the transverse tape charge 29 is detonated, the massive collector 22 and the volume fairing 2 are destroyed.

The detonation pulse from the charge 29 is transmitted to the longitudinal tape charges 31 distributed over the surface along the housing 6, and the ring charge 32 on the nozzle block 9, as a result of which the engine 3 is crushed and the nozzle block 9 is destroyed into parts that are safe for human life at the place of their fall .

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 rocket specialist, showed that it is unknown, and given the possibility of industrial serial production of rockets for active impact on the clouds, it can be concluded that the criteria are met patentability.

Claims (1)

A rocket for active action on clouds, containing a nozzle block with a central electrocapsule sleeve, two longitudinally located channel powder bombs installed with radial clearances relative to the housing, an ignition pulse amplifier, a transfer pyrotechnic charge and a channel smoke bomb with its initiation device located in the head part missiles, characterized in that it is equipped with a receiver located between the igniter pulse amplifier and the electrocapsule sleeve , Duct powder checkers formed with equal arches combustion, separated by a diaphragm and are mounted in a common housing, wherein the ratio of the radial gap t ₁ between the housing and the lower channel propellant checker and size similar clearance t ₂ the upper channel propellant checkers inversely relative diameters of the channels of said pieces , lengths L ₁ , L _{2 of the} mentioned pieces are determined from the following relations:

and

Where

- the Pobedonostsev criterion, and the transfer pyrotechnic charge is made in the form of a moderator of the pyrotechnic composition, the burning time of which is several times longer than the burning time of the channel powder bombs, and the device for initiating the channel bombs of active smoke is placed on the nozzle, and the end of the transfer pyrotechnic charge facing the device the initiation of the channel checker of active smoke, made in the form of a cumulative funnel adjacent to the nozzle.

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