RU111627U1 - CLOCK FOR ACTIVE IMPACTS ON CLOUDS - Google Patents

Abstract

 A rocket for active action on clouds, containing the head part with a channel piece of pyrotechnic charge of active smoke, communicating with the smoke exhaust openings and closed by a cowl, where the initiating self-liquidation mechanism is mounted, a two-section solid-fuel rocket engine, the ignition charge of which interacts with the central electrically ignition sleeve of the nozzle block, blades, characterized in that the charge of active smoke is made of three parts, each of which along the generatric cylindrical surfaces are thermally armored with a coating of heat-resistant asbestos and mounted relative to each other with gaps along the perimeter of which distributed through smoke exhaust openings are made in the body of the head part, while two parts of the active smoke charge are formed from a channel block divided across and the third part is made in in the form of a monolithic pyrotechnic checker blocking the exit to the fairing filled with cast-iron shot.

Description

This utility model relates to devices for changing atmospheric conditions, and more particularly, to meteorological rockets for dispersion in clouds of aerosol generated by the combustion of a pyrotechnic smoke bomb, with the aim of artificially causing precipitation or preventing hail.

The level of this technical field is characterized by a rocket for active exposure to clouds, described in patent RU 21229354, A01G 15/00, 1999, which contains a head part with an active smoke bomb closed by a fairing equipped with a smoke exhaust manifold and a self-liquidating actuator, solid propellant reactive an engine made of two consecutive sections, each of which includes a channel powder gun and an amplifying charge, as well as a nozzle block with aerodynamic blades (stabilizers) and a central minutes elektrokapsyulnoy sleeve equipped ogneperedatochnoy tube to form a flame directed FORS ignition powder checker jet engine running it into operation.

To adjust and optimize the height and range of the rocket, the jet engine is made dual-mode, the channel checkers of each section of which are installed with different gaps relative to the body, which increases the combustion surface and the dynamics of the rocket reaching the mode with increasing flight distance.

Two operating modes of the jet engine are ensured by the sequential functioning of its two sections, in general, for the high-speed rise of the rocket to a relatively high height. In the sections, structural elements are accordingly selected according to the composition, mass and nature of their combustion.

Openings were made in the fairing for the exit of the channel pyrotechnic check generated during combustion through the collector of the head part of active smoke (aerosol), the solid particles of which serve as nuclei of crystallization of moisture or sorbing concentrators of droplet formation in an atmospheric cloud.

A characteristic feature of the described rocket is the equipping of the head with an actuator mounted on the diaphragm facing the amplifier and including a moderator and a detonator capsule of the self-liquidation system.

The actuator of the self-liquidation system is located in the fairing collector; its retarding charge is automatically initiated when the active smoke bomb is ignited. The deceleration time (burning of a pyrotechnic charge) is guaranteed to exceed the operating time of the active smoke bomb. The self-destruction system is triggered by a detonator capsule.

The longitudinal tape explosive charges distributed along the missile’s body, when blown up (after the delay time after the end of the functional equipment of the warhead’s end), create countercurrent flows of fragments directed towards the center, which mutually crush when they encounter a loss of kinetic energy, and the ring tape charges fragment the most massive parts of the rocket into fragments that do not have deadly force.

The disadvantage of the described rocket is the unsatisfactory functional reliability of the dual-mode jet engine under the sequential action of autonomous sections, each of which additionally uses pyrotechnic end-combustion checkers associated with amplifiers to transmit the ignition pulse to stabilize the combustion of channel powder bombs, which significantly reduces the flight range of the rocket.

In addition, the connection of the pyrotechnic checker of the second section of the jet engine with the functional checker of active smoke of the head part through an amplifying charge ensures the ignition of the latter before the rocket enters the treated cloud, which significantly reduces the efficiency of its processing for the intended purpose, reducing the efficiency of precipitation formation.

The noted disadvantages are eliminated in the rocket for active exposure to clouds according to patent RU 2340861, A01G 15/00; F42B 12/36, 2008, which, according to the technical nature and the number of matching features, was selected as the closest analogue of the proposed rocket.

A well-known rocket for active action on clouds contains a head part with an active smoke bomb equipped with means for initiating a self-liquidation system, a collector and a fairing with outlet openings, a jet engine, in a common housing with an annular gap, two channel powder bombs are sequentially mounted through the diaphragm, separated from the functional filling of the head part with a powder moderator, and a nozzle block with a central electrocapsule sleeve and aerodynamic blades stabilizers.

A feature of the known rocket is that the exhaust openings for active smoke are made in a collector diffuser equipped with a pine nozzle for the self-liquidation actuator, and the central electrocapsule sleeve of the nozzle block with the jet engine checkers is communicated by means of an igniter charge adjacent to the end, which are separated by a receiver and powder cannons engine checkers are made with equal arches of combustion.

A disadvantage of the known rocket is the limited range due to the relatively short range, determined by the ineffective gas dynamics of the active smoke generated during the burning of the drafts, emitted through the nozzle block and the outlet openings of the collector diffuser, and also by large losses on the aerodynamic braking of the product during maneuvers on the trajectory.

The technical problem to which this real utility model is directed is to increase the efficiency of the main action for its intended purpose due to the rational distribution of the generated aerosol in a larger volume of the treated cloud, with the accompanying stabilization of the rocket along the trajectory to increase its flight range.

The required technical result is achieved by the fact that in the known rocket for active exposure to clouds containing the head part with a channel piece of pyrotechnic charge of active smoke, communicating with the smoke exhaust openings and closed by a fairing, where the self-liquidation initiating mechanism is mounted, a two-section solid-fuel jet engine, the ignition charge of which interacts with a central electroflamer sleeve of a nozzle block equipped with aerodynamic blades, on offer According to the authors, the active smoke charge is made up of three parts, each of which is formed by heat-resistant asbestos coating on the forming cylindrical surfaces and mounted relative to each other with gaps along the perimeter of which distributed through smoke exhaust openings are made in the body of the head part, while two parts of the active charge smoke is formed from a divided across the channel checker, and the third part is made in the form of a monolithic pyrotechnic checker, blocking the exit to the fairing, filled with cast iron th fraction.

Distinctive features ensured high-performance generation from five ends of the pyrotechnic charge of the head part of the rocket of active smoke, which is emitted directly into the atmosphere in the form of a fine aerosol that effectively acts on the clouds for a longer time.

The implementation of the functional charge of three independently burning from the ends of the parts increases the rate of smoke formation.

Thermal armor of the pyrotechnic charge of active smoke along the forming cylindrical surfaces by means of a coating of heat-resistant asbestos is necessary for the organization of the end combustion of its three separate parts.

The gaps between the checkers of the charge of active smoke act as receivers, where the generated aerosol accumulates, the pressure increases when the active smoke is mixed, which is emitted by transverse jets directly into the atmosphere through coaxial rows of through holes in the head housing.

The communication of the gaps between the parts of the active smoke charge with the through holes distributed around the perimeter of the body ensures a uniform exit of the functional aerosol directly from the place of its generation, which eliminates sludge losses during transportation and the concomitant agglomeration of active particles, i.e., uniform uniform flow of active smoke directly into the processed cloud in the form finely dispersed phase, which ensures increased efficiency of intended use.

In this case, the transverse jets of active smoke serve to provide additional aerodynamic stabilization of the trajectory of the rocket in the cloud being processed, acting as gas rudders.

A monolithic charge of active smoke isolates the beam detonator capsule in the fairing, acting as a temporary moderator to initiate the self-destruction mechanism.

The force of the flame from the solid smoke burnt at the end of the active smoke initiates the detonator beam capsule and the subsequent detonation of the explosive band charges distributed along and across the rocket.

Filling the fairing with cast-iron shot is used to increase the flight range of the rocket in the cloud being treated by stabilizing its flight path as a result of the displacement of the center of mass to its head farther from the pressure center, which is especially important when jet fuel burns out and an active smoke charge.

After the self-destruction of the rocket, the metal fraction of the fairing filling scatters in space and does not pose a danger to living organisms on the earth's surface.

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.

The essence of the utility model is illustrated by the drawing, which has a purely illustrative purpose and does not limit the scope of the claims of the formula. The drawing shows:

figure 1 - the proposed meteorological rocket;

figure 2 - the head part with a functional charge.

Structurally, the rocket includes (Fig. 1) mounted sequentially in the housing 1: a nozzle block 2 with an aerodynamic tail 3, an ignition unit 4, two sections 5 and 6 of a solid propellant engine, a head part 7 carrying a functional charge, and a fairing 8.

A fire transfer tube 9 is fixed in the nozzle block 2, in which a central electrocapsule sleeve 10 is connected, connected with the launcher.

Each section 5 and 6 of the jet engine includes sequentially mounted channel gunpowder block 11, pyrotechnic block 12 face combustion and amplification charge 13, forming a dual-mode rocket engine rocket.

The functional charge of the head part 7 (figure 2) is made of two channel pieces 14 and 15, separated by a transverse gap 16, and a monolithic piece 17 of active smoke adjacent to the fairing 8 and blocking it.

A gap 18 is formed between the monolithic checker 17 and the upper channel checker 14, which communicates with the atmosphere through the radial through holes 19 distributed in the housing 1 (similarly, the transverse clearance 16).

Thus, with the end burning of the checkers 14, 15 and 17, the gaps 16 and 18 serve as storage receivers, and the rows of through holes 19 for direct jet output of active smoke layer by layer into the atmosphere.

All three checkers 14, 15 and 17 of the functional charge of the rocket head 7 on the outer cylindrical surfaces are thermally armored with asbestos shells 20, and the channels of the checkers 14 and 15 with asbestos tubes 21, which ensures their end burning.

A radial detonator capsule 22 is mounted in the fairing 8 (Fig. 1), which, interacting with the charge 17, initiates the actuation of the tape charges 23 and 24 of the explosive distributed over the body 1, respectively, transverse and longitudinal.

Fairing 8 is filled with cast iron shot 25.

the rocket functions as follows.

To launch the rocket from the launcher, an electric pulse is supplied to the electroflamer sleeve 10, when triggered, a force of flame is formed, which is directed by means of the fire transfer tube 9 to the ignition unit 4 of the drafts 11 and 12 of the jet engine section 5, which is output to the calculated mode of operation parameters.

The gaseous products of combustion of the checkers 11, 12 enter the nozzle block 2, where they are dynamically ejected by jets into the atmosphere, developing traction.

Upon reaching a thrust force sufficient to depress the launcher stopper, the missile leaves its guides and starts under the action of jet jets from the nozzle block 2.

Within 2 s, the powder bomb 11 of section 5 burns out, providing a high impulse of specific thrust and rocket propulsion. When the pyrotechnic checkers 12 are burning, gaseous high-temperature products are formed that reactively accelerate the rocket.

During autonomous combustion of the pyrotechnic checker 12, the full jet engine pulse decreases during the next 6 s, as a result of which the rocket’s speed drops slightly and its angular inclination to the horizon occurs during inertial motion along a ballistic trajectory, more gentle.

When the checkers 12 are burned with a thermal pulse, the amplification charge 13 ignites, which with its thermal energy initiates the combustion of the checkers 11 and 12 of the second section 6 of the jet engine. The sequence of functioning of the structural elements of section 6 is similar to that described above for section 5.

The rocket receives an additional thrust momentum during the combustion of the powder checker 11 of section 6, followed by its inertial movement along the ballistic trajectory, when its pyrotechnic checker 12 is independently lit, along which the rocket enters the cloud being processed at a minimum angle to the horizontal.

Next, the heat plume formed during the combustion of the amplifying charge 13 of section 6, channel checkers 15, 14 and the monolithic shatka 17 of active smoke are ignited almost simultaneously.

At the end burning of pyrotechnic checkers 14, 15, 17 from five surfaces, an aerosol is simultaneously actively generated, including finely divided ice-forming reagent or sorbent substance, which serve as active moisture condensation nuclei.

The generated aerosol accumulates in the gaps 16 and 18, where the pressure increases, under the influence of which active smoke through the gas distribution through holes 19 with transverse jets is layer-by-layer ejected into the treated cloud.

In supercooled clouds, ice crystals are formed on dispersed particles of silver iodide, and on the particles of the sorbent from potassium chloride / iodide, a concentration of moisture drops occurs, which precipitate in the form of precipitation.

A feature of the proposed rocket is that the gaseous products of combustion of the functional pyrotechnic charge of the head part that are generated in a large volume are dynamically removed through the volume of the rocket body 1 and its nozzle block 2, free by then, performing an additional function of the working body of the jet engine.

As a result of this, the time spent by an actively moving rocket directly in the cloud being processed increases markedly, which contributes to longer target dispersion of a functional aerosol, increasing the productivity of precipitation initiation.

After burning the shafts 17 with the heat of force of the gaseous products, a beam detonator capsule 22 is initiated.

The detonation wave from the detonator capsule 22 triggers explosive belt charges 23 and 24, from which the rocket collapses transversely and longitudinally into safe parts, which are thrown counter-inward and further crushed without formation of damaging elements dangerous to living organisms in the area of the rocket to the clouds.

In this case, the cast-iron fraction 25 of the filling of the fairing 8, which has been destroyed into parts, crumbles in the atmosphere.

Full-scale tests of prototypes of the proposed rocket confirmed an increase in the effectiveness of the main action; on the processed volume of clouds by a quarter, with an increase in the range of the missile to 20%.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the proposed utility model does not explicitly follow for a pyrotechnic specialist, showed that it is not known, and taking into account the possibility of industrial serial production of rockets for active exposure to clouds, we can conclude on its compliance with the criteria of patentability.

Claims (1)

A rocket for active action on clouds, containing the head part with a channel piece of pyrotechnic charge of active smoke, communicating with the smoke exhaust openings and closed by a cowl, where the initiating self-liquidation mechanism is mounted, a two-section solid-fuel rocket engine, the ignition charge of which interacts with the central electrically ignition sleeve of the nozzle block, blades, characterized in that the charge of active smoke is made of three parts, each of which along the generatric cylindrical surfaces are thermally armored with a coating of heat-resistant asbestos and mounted relative to each other with gaps along the perimeter of which distributed through smoke exhaust openings are made in the body of the head part, while two parts of the active smoke charge are formed from a channel block divided across, and the third part is made in the form of a monolithic pyrotechnic checker blocking the exit to the fairing filled with cast-iron shot.