RU2130164C1 - Antihail rocket - Google Patents

Abstract

FIELD: antihail rockets used for active action on clouds to prevent damage done by hail. SUBSTANCE: antihail rocket includes two-mode engine with boost and sustainer fuel charges, head part with fairing where deceleration system incorporating parachute, opening mechanism in the form of rubber bottle connected through cooler to butt part of boost charge of engine is housed. Bottle is fabricated in the form of torus and cooler is made in the form of mechanical strip put on coil with clearance. Reagent in this case is included in composition of sustainer fuel charge and fairing is provided with meridian cuts. EFFECT: simplified design of antihail rocker and enhanced efficiency of it. 3 cl, 2 dwg

Description

 The invention relates to the field of rocket technology, namely, anti-hail rockets used for active impact on the clouds in order to prevent hail.

 There are various designs of anti-hail rockets, consisting of a propulsion system, a warhead and a security system [1,2].

 Known anti-hail rockets can contain in the head part modular equipment consisting of pyroelements fired in flight [1], or an active smoke bomb providing linear-route seeding [2].

 A disadvantage of the known technical solutions is that the operation of the security system for these missiles is based on the principle of crushing the spent hull by explosion into small, safe pieces at altitudes of the order of 1 - 1.5 km. However, this does not guarantee complete safety, since in case of failure of the explosive device in flight, the charge can detonate when the product hits the ground and cause damage by fragments at a considerable distance from the place of the explosion.

 The closest in technical essence to the claimed object is the anti-hail rocket "Sky" containing a single-mode fuel charge engine, a pyrotechnic checker with a reagent and a braking system including a parachute with an opening mechanism placed between the head and the engine [3 ].

 The disadvantages of the known technical solution include the fact that a single-stage engine cannot provide a gentle trajectory of the rocket in the seeding zone, and therefore, does not fully ensure the reagent is introduced into the cloud layer, limited by temperature levels determined by the exposure technology.

 Another serious drawback of the known technical solution is the complexity of the design of the security system. In fact, this system is a parachute placed in the container, a complex system of opening the container with the help of a special knock-out charge that is triggered after the bursts of active smoke in the head are completely burnt. In addition, the presence of a knock-out charge in the system in itself reduces the safety of rocket use. Another disadvantage of the known technical solution is that the use of an autonomous pyrotechnic checker with a reagent in the head part complicates the design of the rocket, increases its weight and overall dimensions. As a result, the flight range of the rocket and its effectiveness are reduced.

 The aim of the present invention is to simplify the design of anti-hail rockets and increase its effectiveness.

 This goal is achieved by the fact that in a well-known anti-hail rocket containing a two-mode engine with a starting and marching fuel charges, a head part with a cowl, a reagent and a braking system in the form of a parachute with its opening mechanism, the braking system is located inside the cowl, and the system’s opening mechanism is made in in the form of an inflatable balloon and contains a gas cooler connected on one side to the bottom of the marching fuel charge, and on the other hand, to the inflatable balloon, with the starting and marching top The engine’s torrential charges are made of channel and face combustion, respectively, while the reagent is included in the march fuel charge.

 The inflatable balloon is made in the form of a torus made of rubber grade 203 B.

 The fairing of the head part is made of foam and equipped with meridional notches.

 The cooler is made in the form of a strip of aluminum alloy wound on a coil with a gap.

 In FIG. 1 shows a general view of an anti-hail rocket; in FIG. 2 - cross section of its head part with a braking system.

 The anti-hail rocket contains a dual-mode solid fuel engine 1 with a starting 2 and marching 3 fuel charges, while the starting charge is made in the form of a channel combustion charge, and the sustainer - end combustion. The march charge includes the AgJ reagent. A nozzle block 4 with five beveled nozzles 5 is placed in the rear part of the engine 1. An igniter 6 is placed on the inside of the nozzle block 4 and an electrocapsule sleeve 7 is mounted on the outside of the engine. 1 A stabilizer 8 is attached to the engine body 1 at the base of the rocket. which is a glass 9, flexible knitting needles 10, the canvas 11 and the slings of the parachute 12. The glass 9 contains holes 13 on the side surface and is attached to the end of the engine 1. An inflatable balloon 14 is attached to the side surface of the glass 9, made made of heat-resistant flexible and durable rubber of type 203 B. A cylinder made of heat-resistant flexible and durable rubber of type 203 B. The cylinder 14 has a torus shape and covers the side surface of cylinder 1. Between the glass 9 and the end part of the engine 1 there is a cooler 15, which is made in in the form of a tape 16 wound on a reel 17 with a gap. The coil 17 contains at the ends of the hole 18, through which the inflatable balloon 14 is gasdynamically connected with the marching fuel charge 3. The canopy of the parachute 11 is attached to the spokes 10. The spokes 10 are in turn attached to the bow of the glass 9 and provided with slings 12 attached to the base of the glass 9. An inflatable balloon 13, spokes 10 with a web of parachute 11 and slings 12, pressed to the side surface of the glass 9, form a braking system. The braking system is enclosed in a conical radome 19 made of foam. On the inner surface of the fairing 19 provided meridional notches (not shown).

 Anti-hail rocket operates as follows.

 Using the electrocapsule sleeve 7 and the igniter 6, the starting fuel charge of the channel combustion 2 is ignited, and the rocket leaves the launcher in a given direction. When the fuel charge is burning, the maximum flight speed of the rocket is ensured in the initial portion of the trajectory, and the rocket is brought to a predetermined level of the cloud layer, where the impact is necessary. Then, from the charge 2, the marching fuel charge of the end combustion 3 is ignited, which ensures the rocket moves along a trajectory close to horizontal. Under these conditions, the AgJ reagent, which is part of the sustainer fuel charge 3, is released together with the exhaust gases of engine 1 into the atmosphere, and interacting with the cloud environment, neutralizes the processes of city formation. At the moment of the burning of the marching fuel charge 3, the gases from the engine 1 through the holes 18 in the coil 17 pass through the cooler 15 and the cup 9, and then enter the inflatable balloon 14. When moving through the cooler 15 and the cavity of the cup 9, the gases are cooled to a predetermined level, which eliminates combustion of the inflatable balloon 14. Then, under the action of compressed gases, the balloon 14 expands, destroying the conical fairing 19 along the lines of the meridian notches. In this case, a parachute is opened (Fig. 2), which is essentially an umbrella, and the spent rocket casing is lowered to the ground.

 The departure from the classical scheme and the use of the marching fuel charge simultaneously as an aerosol generator, as well as the adopted design of the braking system with an inflatable balloon and cooler, made it possible to significantly simplify the design of the rocket and increase its efficiency.

 The engine, as well as the adopted rocket braking system, are technological and do not require the use of unique equipment. At present, an experimental batch of engines has been manufactured, the operability of which is confirmed by fire tests.

 The proposed anti-hail rocket is one of the main elements of the newly created new automated environmentally friendly cheap and safe anti-hail complex "Alan".

Sources of information
1. Abshaev M.T., Klinger B.A. Guidelines for the use of anti-hail complex "Crystal" for active impact on hydrometeorological processes. - L .: Gidrometeoizdat, 1989, p. 6-18.

 2. Bibiliashvili N.Sh., Burtsev T.T., Seregin Yu.A. Guidelines for the organization and conduct of anti-hail works. - L .: Gidrometeoizdat, 1981, p. 40-45.

 3. Manual on rocket and artillery support of active impacts on hydrometeorological processes. / Abshaev MT, Burtsev II, Shelkovy G. T., Kuznetsov IT et al. - L .: Gidrometeoizdat, 1988, p. 175-177 - prototype.

Claims (4)

 1. Anti-hail rocket containing a two-mode engine with starting and marching fuel charges, a head part with a cowl, a reagent and a braking system, including a parachute with an opening mechanism, characterized in that the braking system is located inside the cowling, and the opening mechanism of this system is made in the form of an inflatable the cylinder and contains a gas cooler connected on the one hand to the bottom of the sustainer fuel charge, and on the other hand to the inflatable balloon, while the reagent is included in the sustainer fuel of engine power.  2. The rocket according to claim 1, characterized in that the inflatable balloon is made in the form of a torre of rubber brand 203 B.  3. The missile according to claim 1, characterized in that the fairing of the head part is made of foam and is equipped with meridional notches.  4. The rocket according to claim 1, characterized in that the cooler is made in the form of a strip of aluminum alloy wound on a coil with a gap.

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