RU2282821C2 - Guided missile with non-isotropic fragmentation warhead "alkonost" - Google Patents

Abstract

FIELD: armament.

SUBSTANCE: the guided missile with a radial non-isotropic fragmentation warhead has a control section including the guidance system, roll-stabilized system and the system of non-contact destruct, control surfaces and wings, explosive charge, and a jet solid-propellant engine with a change of solid propellant. The charge of the jet engine is made of a detonationable solid propellant and positioned in the body in parallel with the explosive charge with a tight engagement with it on the lateral surface through an explosion-conducting longitudinal partition.

EFFECT: more rational use of the energy of solid propellant.

10 cl, 7 dwg

Description

The invention relates to weapons, and more specifically to guided missiles with radially directed fragmentation warheads. The domestic anti-aircraft guided missile 9M83 of the S-300V military anti-aircraft complex ("Technique and Armament", No. 5-6, 1999, p.24) contains the launch and march stages.

The marching stage contains a control compartment, including guidance systems, roll stabilization and non-contact detonation, a warhead of radial directional action and a solid propellant rocket engine.

The main disadvantage of a rocket is the irrational use of the chemical energy reserve of the rocket’s main energy source - a solid fuel charge. The initial mass of solid fuel can be up to 50% of the mass of the march stage, and the unburned mass of fuel at the time of detonation of the warhead can be up to 10% at long ranges and up to 30-40% at short ranges. At the same time, the mass of the explosive charge of the warhead usually does not exceed 5% of the mass of the rocket. Another disadvantage is the small contact area of the explosive with a set of ready-made striking elements (GGE), which impairs the transfer of explosive charge energy to the set of GGE.

This decision is aimed at eliminating these shortcomings. The technical solution consists in the fact that the charge of the jet engine is located parallel to the explosive charge with close contact with it on the side surface through the explosive longitudinal partition and is made of detonating solid fuel, the engine uses side combustion of the charge from the side opposite to the location of the warhead the partition is made with a thickness that ensures the transfer of detonation from the explosive charge to the charge of solid fuel.

Moreover, according to the invention, in the solid fuel charge from the side opposite its contact surface with the explosive charge, a longitudinal recess is made, and the fragmentation warhead is made with a cross section of a segment or close shape and contains an explosive charge and a layer of ready-made striking elements laid on the surface of the charge.

Also according to the invention, the finished striking elements are made of steel or heavy alloys based on tungsten and in the form of compact bodies with a shape that ensures their tight packing on the surface of the explosive charge. Ready striking elements are made in the form of rods laid on the surface of the explosive charge.

In addition, according to the invention, the rods on the surface of the charge are stacked parallel to the axis of the projectile and connected alternately by the ends and can be stacked on the surface of the charge at an angle of 2 ... 5 degrees to the generatrix, and a metal plate with extruded hemispherical recesses is laid on the surface of the charge of solid fuel with the tops of the recesses facing the charge side.

The non-contact blasting system is configured to automatically take into account the reduction in the throwing speed of finished striking elements with an increase in flight range.

The invention is illustrated by drawings, which depict:

figure 1 presents a longitudinal section of the march stage of the rocket,

figure 2 is a cross section of a rocket on the engine,

figure 3 - configuration of the cross section after the burning of part of the fuel,

figure 4 - configuration after undermining,

figure 5, 6 is a diagram of the destruction of targets by the directed field of the GGE,

and Fig.7 is a diagram of the defeat of an air target with a “strike lash."

Shown in figure 1, the missile, made according to the aerodynamic scheme "duck", contains in front of the control compartment 1 with rudders 2, having access to the rest of the rocket through the igniter 3 and detonator 4. The control compartment is connected to the engine casing 5, made of composite material, for example fiberglass, and separated by a longitudinal partition 6 along the entire length. On the inner surface of the casing there is a layer of thermal protective coating 7. In the upper part of the casing there is a charge of detonating solid fuel 8, representing, for example, a mixture based on RDX. A longitudinal recess 9 is located along the entire length of the side surface of the charge, and a warhead 10 is located in the lower part of the housing, consisting of a charge of explosive 11 and a layer of ready-made striking elements (GGE) 12 made of steel or heavy alloys, for example, based on tungsten, a shape that allows for their tight packing, for example, in the form of a cube, a hexagonal prism (in FIGS. 1-4, the GGE of a spherical shape is conventionally shown). Laying GGE 12 can be performed single-layer or multi-layer.

GGE laying can be replaced by other types of metal striking elements, including a fragmentation plate of predetermined crushing, a plate with hemispherical recesses extruded on it, intended for the formation of explosively formed strikers (“shock nuclei”), a set of rods with a length equal to the length of the warhead, laid by charge generators intended for the formation of so-called “shock lashes”, etc.

At the rear of the casing there is a lattice diaphragm 13 and a nozzle 14. On the surface of the casing there are wings 15.

To ensure a constant combustion surface of solid fuel on the surface of the longitudinal recess 9 can be placed longitudinal grooves 16 (figure 2).

The action of the rocket is as follows. After starting and separating the starting stage, the igniter 3 ignites the solid fuel charge on the surface of the longitudinal recess 9. The combustion of the charge continues throughout the entire flight time to the target (Fig. 3). When approaching the target, the control system determines the miss side and targets the warhead by turning the rocket around its longitudinal axis (roll). The warhead is detonated by the detonator 4. In this case, detonation is transmitted through the partition 6 of the unburned part of the solid fuel charge, which enhances the overall fragmentation and compression effect. Forced guidance of the detonation front along the entire length of the charge of solid fuel ensures the completeness of detonation of solid fuel compositions with a fairly low content of expensive blasting explosives, such as RDX or HMX.

As a result of the explosion of explosive charges and solid fuel, a GGE flow is formed, directed towards the target (Figs. 4, 5, 6).

Due to the fact that during the flight the thickness of the solid fuel layer decreases continuously and, as a result, the estimated speed of the GGE throwing drops, the determination of the moment of detonation, carried out according to the condition of covering the target with the GGE flow with the construction of a vector velocity triangle, is carried out automatically taking into account the decrease in the speed of GGE throwing with increasing flight range.

A more effective destruction of an air target can be achieved by using a rod warhead. Figure 7 shows the action of the core warhead having a longitudinal stacking of rods alternately welded with front and rear ends. After the explosion, due to the presence of a vector speed difference at the ends of the laying, the rods diverge, forming the so-called “impact lash”, which is capable of making continuous cuts to airborne gliders with their subsequent destruction. Laying the rods on most of the length of the rocket allows you to get long whips (up to 10 ... 20 m), which will ensure the defeat of targets with significant misses. “Impact lashes” can also be used to destroy ground objects representing a spatial composition of linear elements (bridge trusses, power lines, antenna fields, radio relay masts, radar masts, etc.).

Claims (10)

1. Guided missile with a radially directed fragmentation warhead, containing a control compartment, including guidance, stabilization systems and roll non-contact blasting system, rudders and wings, explosive charge and solid propellant rocket engine with a charge of solid fuel, characterized in that the jet engine charge is made from detonating solid fuel, wherein said charge is located in the housing parallel to the explosive charge with close contact with it along the lateral surface of the vzryvoprovodyaschuyu longitudinal bulkhead. 2. Guided missile according to claim 1, characterized in that in the charge of solid fuel from the side opposite its contact surface with a charge of explosive, a longitudinal recess is made. 3. Guided missile according to claim 1, characterized in that the fragmentation warhead is made with a cross section of a segmented or close to it shape and contains an explosive charge and a layer of ready-made striking elements laid on the surface of the charge. 4. Guided missile according to claim 3, characterized in that the finished striking elements are made of steel or heavy alloys based on tungsten. 5. Guided missile according to claim 3, characterized in that the finished striking elements are made in the form of compact bodies with a shape that ensures their tight placement on the surface of the explosive charge. 6. Guided missile according to claim 3, characterized in that the finished striking elements are made in the form of rods laid on the surface of the explosive charge. 7. Guided missile according to claim 6, characterized in that the rods on the surface of the charge are stacked parallel to the axis of the projectile and are connected alternately by the ends. 8. Guided missile according to claim 6, characterized in that the rods are stacked on the surface of the charge at an angle of 2-5 ° to the generatrix. 9. Guided missile according to claim 3, characterized in that a metal plate is laid on the surface of the charge of solid fuel with hemispherical recesses extruded thereon, with the tops of the recesses facing the charge side. 10. Guided missile according to claim 1, characterized in that the non-contact blasting system is configured to automatically take into account the reduction in throwing speed of the finished striking elements with increasing flight range.

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