RU2121652C1 - Method of hitting of lightly armored equipment and personnel and ammunition for its realization - Google Patents

Abstract

FIELD: ammunition, specifically, mines laid underground and exploding above ground after escape. SUBSTANCE: ammunition with target detector is put into ground. Jet engine with two-stage reduction of thrust is started after detection of target and flight module of ammunition is brought out of ground. It is divided into subammunition by explosion which are scattered under action of jet streams with various horizontal components of speed. Flight of subammunition to targets is stabilized by reduction of part of their mass. Ammunition proper is manufactured in the form of container with cover that houses flight module with solid-propellant jet engine fitted with igniter with powder weights as well as bursting charges coupled by blasting system, subammunition and target detector. Jet engine is placed on top of flight module and its peripheral nozzles are positioned with inclination to longitudinal axis of ammunition. Subammunition with stabilizers are located in two cassette containers with central bursting charges put one after the other behind jet engine. Some of subammunition in each container is enclosed in additional metal envelope which carries system of attachment of subammunition. Each subammunition has capability to drop part of its mass. EFFECT: expanded zone and efficiency of target hitting. 10 cl, 8 dwg

Description

 The invention relates to the field of ammunition and blasting, in particular to ground "jumping" mines that explode after departure from the ground, and can be used to destroy low-flying and lightly armored targets approaching the shores.

 There is a known method of defeating manpower and armored vehicles, namely, that the ammunition is installed in the ground, equipped with a target detection sensor, a jet of ammunition is removed from the ground at the command of the target detection sensor and undermined (see, for example, the FRG patent No. 3048752 for 1982 year, CL F 42 B 23/16).

 The disadvantage of this method is the fact that the target area remains small and only one object of technology can be hit.

 Known ammunition for the destruction of manpower and armored vehicles (related to ground "jumping" mines), containing a launch container with a cover, a flight module, including a solid fuel rocket engine with a powder charge of the igniter and charge, submunitions, a target detection sensor (see, for example, German patent N 2509699 for 1976, CL F 42 B 23/16).

 In a known munition, the number of striking elements (submunitions) is increased, which naturally increases the likelihood of hitting several objects of equipment and the zone of destruction is increased due to the firing of each submunition from the flight module along a path close to the generatrix of the cone with a given elevation above the ground of the flight module.

 A disadvantage of the known ammunition is the same insufficient target destruction zone.

 When developing the invention, the problem was solved to further increase the effectiveness of ammunition by expanding the target area of the targets, stabilizing the flight module to evenly distribute submunitions over the affected area.

 This problem is solved by the fact that in the known method of defeating manpower and armored vehicles, in which the ammunition is installed in the ground, it is equipped with a target detection sensor, the ammunition is removed from the ground by command of the target detection sensor and detonated, according to the invention, part of the ammunition is removed from the ground and the part of the ammunition that is removed from the ground (flight module) is dispersed stepwise with a decrease in the thrust force, then the flight module is divided into submunitions on the trajectory of the flight by the remaining the action of a jet stream and scatter submunitions with different horizontal components of the speed of dispersion, and when scattered, submunitions stabilize with the shooting of part of the mass. Effectively, if the flight module is accelerated for 0.01 - 0.15 s with an acceleration equal to (5.5-8) gravitational acceleration, and during the subsequent (1-15) with an acceleration equal to (4-4 5) acceleration of gravity. It is effective if the horizontal component of the dispersion rate of some submunitions exceeds 2.5-3.5 times the magnitude of the horizontal component and the dispersion rate of other submunitions. Also by the fact that in a known munition containing a launch container with a lid, a flight module comprising a solid fuel rocket engine with a powder charge of an igniter and a charge, submunitions, a target detection sensor, according to the invention, a solid fuel rocket engine located on top of a flight module is made with obliquely located to the longitudinal axis of the munition with peripheral nozzles, and submunitions with stabilizers are located in at least two cluster containers located but one after the other and behind the jet engine, equipped with central explosive charges connected by a detonation system, while the powder charge of the charge igniter is equipped with an additional powder charge, and part of the submunitions of each cluster container is placed in an additional metal shell on which the system for attaching submunitions is located, while part of the mass of the submunition is discharged. Effectively, if the cartridge container is made in the form of a casing and two rows of submunitions arranged concentrically and separated by an additional metal shell, while the inner row of submunitions is installed with a radius gap relative to the central explosive charge, and the system for attaching submunitions is made in the form of pins radially mounted in holes of an additional metal shell, crackers in the form of trapezoidal plates mounted on each end of the stud and liners made in the form of plates with trapezoidal thickenings along the long sides of the plate and installed in the second row of submunitions between each two pairs of submunitions of the second row. It is necessary that the centers of the outlet cross sections of the peripheral nozzles of the solid propellant jet engine are placed at a diameter of 0.65 - 0.8 of the diameter of the cartridge container.

Effectively, if the powder charge of the igniter charge of the solid propellant jet engine is 0.15-0.25 of the mass of the main powder sample. It is necessary that the central explosive charge of the cartridge container was made of a porous explosive with a detonation velocity (2-5) • 10 ³ m / s, lined with a synthetic shell. Conveniently, if the lid of the launch container is made convex, mainly along a second-order curve, and at least three thinning are made on its surface, converging in its geometric center on the longitudinal axis of the munition. Reliably, if the starting container is equipped with a hot gas generator, made in the form of a sample of smoky gunpowder connected to a solid propellant jet engine. Effectively, if the stabilizer of the submunition is made in the form of linen tapes, mounted at one end on the submunition housing, and the other interconnected and laid in a resettable safety cap mounted on the housing. It is convenient if the safety cap is mounted on the submunition housing with adhesive tape.

 The totality of the distinguishing features of the decision to the applicant is unknown, which is proof of the novelty of the proposal, and each of the features of this combination does not follow clearly from the prior art, which is evidence of the presence of an inventive step in the proposal. Moreover, the authors emphasize the presence of a causal relationship between the totality of the essential features of the claimed inventions and the achieved technical result.

 The invention is illustrated by drawings. In FIG. 1 shows the ammunition at the moment of exit from the ground of a flight module with a working jet engine, while the lid of the launch container is opened; in FIG. 2 - general view of the ammunition; in FIG. 3 - a fragment of the cover of the launch container; in FIG. 4 is a part of section AA in FIG. 2 with fastened rows of submunitions; in FIG. 5 is a graph of the scatter velocity vectors of both rows of submunitions at the moment of undermining of the central explosive charges; in FIG. 6 - the initial phase of stabilization of submunitions after undermining the central explosive charges; in FIG. 7 - the moment of separation of the resettable safety cap and the output of the stabilizer submunition; in FIG. 8 - the final phase of stabilization of submunition.

 In general terms, the method is implemented as follows.

 Ammunition (as a material object) in the form of a launch container 1 with a lid 2 and a target detection sensor 3 is installed in the ground to a depth of 1-2 m. When there is manpower and equipment moving along the ground, water (to shore), air (low) of the target They identify and, at the command of a target detection sensor (operator's option), remove from the ground a part of the ammunition (flight module 4) with a jet stream and accelerate it stepwise with decreasing thrust. Within 0.01 - 0.15 s with acceleration (5.5-8) of gravity acceleration, and over the next 1-15 seconds with acceleration (4-5.4) of gravity acceleration. Measure the height of the flight module or the magnitude of the flight time. Undermine the flight module is divided into submunitions 5 with the continuing effect of a jet stream. And submunitions are scattered with different horizontal components of the dispersion speed, which for one group of submunitions exceeds 2.5-3.5 times the value of the specified component of the dispersion velocity than for the other group. When scattered, stabilize the submunition with the shooting of part of its mass, and then parachute to the target.

 Ammunition, in addition to the above elements, is made as follows. The lid of the launch container is made convex, mainly along a second-order curve, for example, a hyperbole, and is weakened by at least three recesses 6. The recesses are needed to open the sealed launch container. The recesses converge in the geometric center of the lid on the longitudinal axis of the munition.

The flight module further includes a solid-fuel engine 7, placed in a metal housing on top of the flight module. In this case, the jet engine is made with peripheral nozzles 8 inclined towards the longitudinal axis of the flight module. The centers of the output sections of the nozzles of the solid fuel jet engine are located on a diameter (D ₁ ) of 0.65-0.8 of the diameter (D ₂ ) of the cassette container 9, 10 arranged sequentially one after another along the longitudinal axis. Each cassette container in the casings 9, 10 contains a central explosive charge 11 associated with a blasting system (not shown in the drawing) and a central explosive charge of the second cassette container by electrical communication (not shown). The blasting system also includes a timer and a power source. Each cluster container contains two rows of submunitions, the outer 12 and inner 13, which are arranged concentrically and separated by an additional cylindrical metal shell 14. At the same time, the submunitions are interconnected in rows and with a metal shell by means of radius pins 15 installed in openings 16 of the additional the metal shell of rusks 17 and liners 18. The inner row of submunitions is installed from the central explosive charge at a certain distance, selected experimentally, using odya integrity of the submunitions in the separation of the munition and giving them different expansion speeds. The insert is made in the form of a plate with trapezoidal thickenings along the long ends of the plate and is installed in the outer row in the intervals between each two pairs of submunitions, while the cracker is made in the form of a trapezoidal section plate and is installed on each end of the stud and is tightened by nut 19. The central bursting charge is made of porous explosives with a detonation velocity of (2-5) 10 ³ • m / s, for example, alumotol, lined with a synthetic shell 20, for example bakelite.

 The powder sample of the igniter of the charge of a solid propellant jet engine is equipped with an additional sample component (0.15-0.25) of the mass of the main powder sample (not shown).

 The launch container may be equipped with a hot gas generator, made in the form of a sample of gunpowder (not shown in the drawing) connected to a solid propellant jet engine.

 A hot gas generator is required to reliably open the lid of the launch container. The submunition is equipped with a stabilizer made in the form of linen tapes 21, mounted at one end on the submunition housing and connected to each other and laid in a removable safety cap 22 mounted on the housing and fastened with adhesive tape (not shown).

 To implement the proposed method of defeating manpower and armored vehicles, the ammunition is installed in the ground. For "heavy soils" (rock, frozen clay, etc.), a hot gas generator in the form of a sample of smoke gun powder connected to a solid propellant jet engine (not shown) is added to the sealed launch container to help the solid fuel jet engine. When the flight module of the ammunition is removed from "light", unfrozen and especially sandy loose soils, it is not necessary to supply a launch container with a hot gas generator. It is very important that the center of mass of the flight module is located in the aft part, while the pulling jet engine is placed at the top of the flight module, which, according to the well-known theory, ensures its stability in flight, which was confirmed by experiment. In addition, the stability of the flight module on the trajectory increases due to the fact that the longitudinal axis of the peripheral nozzles (and 4 of them) are inclined to the longitudinal axis of the munition and the center of the output sections of the peripheral nozzles are located at a diameter of 0.66 of the diameter of the cartridge container. The jets of the products of combustion of the jet stream, washing the upper cassette container at a speed of 1800 m / s, capture an incoming air stream between the jets, and a “tunnel” effect arises and the flight module moves in a kind of “cocoon”, which contributes to stable flight along with the stability platform formed by the difference in the diameters of the solid propellant jet engine and the cassette container (by analogy with the solution known by patent N 2070960).

The implementation of the proposed method and the operation of the ammunition begins at the command of the target detection sensor. The solid fuel charge igniter, as mentioned above, reinforced with an additional powder hinge in the amount of 0.2 of the mass of the main powder hinge, helps the jet engine open the lid of the launch container through the recesses that are made in the thickness of the metal of the lid like a lotus, and remove the products of combustion of the "foam" of the soil above the ammunition. By the jets of a jet engine, the flight module (as part of the ammunition) is discharged into the atmospheric air zone (see Fig. 1). The achieved increase in thrust by 22% at the time of opening the container and the output of the flight module into the atmosphere (0.01-0.15) s provides the flight module with an acceleration of about 6.5 accelerations of gravity. Further, a four-nozzle jet engine using ballistic solid fuel operates with a combustion temperature T = 2600 ^o K and a single impulse J _ed 160 kg • s / kg. At the second stage of the flight of the flight module for (1-15) s, the engine provides an acceleration corresponding to 4.7 accelerations of gravity. Cassette containers contain two rows of submunitions, with 14 in the outer row and 7 submunitions in the inner row. They are fastened with an additional cylindrical metal shell installed between the rows of submunitions, seven radial studs installed in the holes of the additional metal shell and held on both sides by nuts, fourteen crackers installed on the ends of the studs and supported by nuts, and seven liners installed between each pair submunitions of the outer row. Inserts and crackers are made of aluminum alloy and do not deform submunitions.

The central explosive charges in each cartridge container are made of porous explosive with a detonation velocity of about 3.2 • 10 ³ m / s and are interconnected (for insurance) by additional detonators and a system for their detonation. The design of cluster containers, their relative position and position relative to the jet engine is aimed at stably and uniformly dispersing submunitions over a given area of destruction.

 The system of undermining the central explosive charges after a predetermined flight time gives a command to detonate when the jet engine is running. This is a very important circumstance, since the flight module is stabilized at the moment of blasting and flies above the blasting cloud. The design of the cartridge container and the ratio of its structural elements, as experiments have confirmed, provides a horizontal component of the expansion speed of the outer row of submunitions 2.5-3.5 times higher than the horizontal component of the expansion speed of the inner row of submunitions (see Fig. 5), which ensures increased area of damage. This is achieved by a combination of many design factors, including the magnitude of the radial gap between the central explosive charge and the inner row of submunitions, the detonation speed, the strength of the additional metal shell, the height of the submunition and the vertical velocity component gained by the flight module, the strength of the shells of the submunitions, and finally the mutual influence of the action of two central explosive charges, increasing the vertical component of the expansion velocity of the upper cassette container 9.

 Due to the thrust of a jet engine during an explosion, a more uniform distribution of submunitions over the area of destruction is additionally achieved. Immediately after the separation of ammunition into submunitions, their flight is unstable (see Fig.6). The stabilization of the orientation of the submunition begins from the moment the safety cap covering the submunition stabilizer is removed. Removing (shooting) 22 removable safety cap is made due to the pressure of gases penetrating under the cap and adhesive tape holding the safety cap, arising from the explosion of the Central bursting charge. The submunition stabilizer in the form of linen tapes is straightened, finally stabilizes the submunition and parachutes it to the target.

 The proposed ammunition and method of destruction is much more effective than the known ones and allows you to automate the process of guarding the territory and reduce the consumption of ammunition by a hundred times.

 For the claimed inventions, as described in the independent claims, the possibility of their implementation using the methods and means described in the application and known prior to the priority date is confirmed.

 In turn, the claimed inventions, when implemented, are able to achieve the result perceived by the applicant. Therefore, they meet the criterion of "industrial applicability".

Claims (12)

 1. The method of destruction of lightly armored vehicles and manpower, namely, that ammunition is installed in the ground with a target detection sensor, when a target is detected, a jet engine is launched and the ammunition flight module is brought out of the ground, submunitions are scattered and hit targets, characterized in that the flight module above the ground, step-by-step is accelerated with a decrease in the thrust of a jet engine, undermining the flight module is divided into submunitions with the continued effect of jet jets and the submunitions are scattered from different and horizontal components of velocity dispersion and stabilize the flight submunitions shooting of their mass.  2. The method according to claim 1, characterized in that the flight module is accelerated during the first 0.01 - 0.15 s with an acceleration equal to 5.5 - 8.0 accelerations of gravity, and in the next 1 - 15 s acceleration 4.0 - 5.4 acceleration of gravity.  3. The method according to claim 1 or 2, characterized in that the horizontal component of the dispersion speed of one part of the submunitions exceeds 2.5 - 3.5 times the horizontal component of the dispersion speed of the other part of the submunitions.  4. Ammunition for hitting lightly armored vehicles and manpower, comprising a launch container with a lid, a flight module with a solid fuel rocket engine with an ignition powder, charge and submunitions, a target detection sensor, characterized in that the jet engine is located on top of the flight module and is made with peripheral nozzles located obliquely to the longitudinal axis of the munition, submunitions with stabilizers are placed in at least two consecutively behind each other for p with an active engine of cartridge containers with central explosive charges connected by a detonation system, the powder charge of the jet igniter charge is equipped with an additional powder sample, with a part of the submunitions in each cartridge container placed in an additional metal shell on which the submunition fastening system is placed, and each submunition is made the possibility of dropping part of the mass.  5. Ammunition according to claim 4, characterized in that the cartridge container is made in the form of a casing, in which two rows of submunitions are concentrically arranged and fixed between themselves by an additional metal sheath, while the inner row of submunitions is installed with a radius gap relative to the central explosive charge, and the system for attaching submunitions is made in the form of studs radially mounted in holes of an additional metal shell with crackers in the form of trapezoidal section plates at their end x and inserts made in the form of plates with trapezoidal thickenings along the long sides of the plate and installed between each pair of submunitions of the outer row.  6. Ammunition according to claim 4 or 5, characterized in that the centers of the output sections of the jet engine nozzles are placed on a diameter equal to 0.65 - 0.8 of the diameter of the cartridge container.  7. Ammunition according to any one of paragraphs.4 to 6, characterized in that the mass of the additional powder charge of the igniter charge of the jet engine is 0.15 - 0.25 of the mass of the main powder sample. 8. The ammunition according to claim 4, characterized in that the central explosive charge of the cartridge container is made of porous explosive with a detonation velocity (2 - 5) • 10 ³ m / s, enclosed in a synthetic shell.  9. The ammunition according to claim 4, characterized in that the lid of the launch container is made convex, mainly along a second-order curve, and at least three thinning are applied on its surface, converging in its geometric center on the longitudinal axis of the ammunition.  10. Ammunition under item 4 or 9, characterized in that the launch container is equipped with a hot gas generator in the form of a sample of smoky gunpowder connected to a jet engine.  11. Ammunition according to claim 4, characterized in that the stabilizer of each submunition is made in the form of tapes attached at one end to the submunition body, the other ends of which are interconnected and laid in a safety cap mounted on the submunition housing with the possibility of dropping.  12. Ammunition according to claim 11, characterized in that the safety cap is attached to the submunition body with adhesive tape.

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