RU2208759C2 - Fragmentation-cluster projective - Google Patents

Abstract

FIELD: fragmentation projectiles. SUBSTANCE: the projectile has an explosive charge and a bottom fuse mounted in the body with a front bottom, installed on which is a block with tightly laid prefragmented injuring elements (PIE) and an easily detachable head cap filled with low-dense material. The PIE block is made for its probable replacement, just before a shot inclusive. The replaceable blocks are furnished with prefragmented injuring elements of a different mass. The PIE block rests on the front bottom of the body through a diaphragm, which damps the compression action of pressure in the front of the impact wave at detonation of the explosive preserving the geometric integrity and spatial propagation of the injuring elements. A device for a quick extraction of the PIE is attached to the diaphragm. Correlation of the projectile body with the PIE block by means of device preventing a turn-through makes it possible to prevent angular relative displacement of the PIE block at a gyroscopic longitudinal stabilization of the projectile in the flight trajectory, excluding additional disturbances, which ensures the required accuracy of fire. EFFECT: enhanced efficiency of injuring action of the projectile on target with a different degree of protection. 15 cl, 1 dwg, 1 tbl, 1 ex

Description

 The invention relates to ammunition characterized by a warhead, and more particularly to fragmentation shells, the shell or body of which contains many individual elements having an axial and circular field of destruction.

 A known design of a fragmentation-beam projectile containing an explosive charge (explosive) and a bottom fuse placed in a housing with a front bottom (RF patent 2137085, F 42 V 12/32, publ. 10.09.99 in bull. 25). At the bottom there is a sleeve with a multilayer block of tightly laid ready-made striking elements (GGE) of predominantly hexagonal profile and a conical fairing hood. A block of finished striking elements rests on the front bottom through a damper disk. In the block between the layers of elements placed aperture.

 The disadvantage of this rotating fragmentation-beam projectile is the placement of the GGE block of a coaxial design of relatively large mass in a thin-walled cowl cover, which requires high precision assembly operations in production.

 By the number of coinciding features and technical nature, the closest to the proposed fragmentation-beam projectile is a projectile (RF patent 2018779, F 42 В 12/32, publ. 30.08.94 in bull. 16), having a body with an explosive charge and a bottom fuse with a detonator and inertial shock mechanism with a deceleration element. The front of the body is made with a conical or curved surface facing the apex to the bottom of the projectile. The head cap is filled with low-density material and in front of it has a reaction unit connected to the bottom fuse. A sleeve with a GGE block is installed between the front of the body and the head cap. The striking elements are made in a form that ensures their tight packing.

 The disadvantage of this fragmentation-beam projectile is the lack of fragmentation effect on targets with varying degrees of protection. It is known (V.A. Odintsov. Axial-action ammunition designs // MSTU named after N.E. Bauman, 1995, p. 97) that the probability of hitting a target of a certain type depends on the mass of the striking element and its speed, however, the design of the projectile the prototype does not allow before its use to change the mass of the GGE in the block.

 The problem to which the present invention is directed, is to increase the efficiency of the fragmentation-beam projectiles of a certain caliber for targets of various types.

 The technical solution to the problem lies in the fact that in the well-known fragmentation-beam projectile containing an explosive charge and a bottom fuse mounted in a housing with a front bottom, on which a unit with densely laid GGE and a head cap filled with low-density material is installed, according to the invention, the projectile is made with the possibility of replacing the GGE block, including immediately before the shot. Replaceable blocks are equipped with ready-made striking elements of various weights. The GGE block rests on the front bottom of the hull through a diaphragm, which dampens the compressive action of pressure in the front of the shock wave during detonation of the explosive, while maintaining the geometric integrity and spatial distribution of the damaging elements. A device is mounted to the diaphragm for quick extraction of the GGE block.

 To ensure convenient access to the GPE block, the head cap of the projectile is made easily removable.

 The interconnection of the shell of the projectile with the GGE block by means of an anti-rotation device allows preventing the relative angular displacement of the GGE block during gyroscopic longitudinal stabilization of the projectile along the flight path, eliminating additional disturbances, which ensures the required firing accuracy.

 The mass of ready-to-use striking elements is calculated for specific types of targets according to the criterion of the maximum probability of a single-shot hit.

The projectile is equipped with inserts made of material with a density not exceeding 5 kg / m ³ .

 The replaceable block of finished striking elements has a layered or mixed stacking of striking elements of various masses.

 GGE are made of steel or alloys based on tungsten.

An insert of explosive material in the form of a straight truncated cone with a base radius R _d = (0.12-0.14) d and a smaller radius R _r = ( 0.08-0.1) d, height H = (0.07-0.09) d and, facing a large base towards the bottom of the projectile.

 The invention is illustrated by a specific example, which is not the only possible one, but clearly demonstrates the implementation of the achievement of a new set of essential features, which is stable in nature, creating the effect of the sum as a new technical result obtained when using the projectile of the invention.

 The invention is illustrated in the drawing, which presents a schematic diagram of a fragmentation-beam projectile.

 In case 1 of an artillery shell made of high-carbon steel (for example, 60С2, 80Г2С or 110Г2С), a low-sensitive composition of explosives 2 (for example, triaminotrinitrobenzene) is placed, a bottom fuse 3, a block of ready-made striking elements 4, and a head cap 5 are installed.

 The striking elements of block 4 are made in a form that allows them to be tightly packed (for example, cubic).

 The cap 5 is filled with a low-density material (for example, polyurethane foam) and connected to the shell of the projectile by means of an easily removable connection (for example, a bayonet-type lock). It does not interfere with the passage of ready-to-use striking elements at the time of the detonation of the projectile.

 In order to reduce the angle of expansion of the GGE along the axis of the explosive charge, an insert 6 is placed in the form of a truncated cone made of non-explosive material (for example, wood).

 The GGE block is equipped with a rotation prevention device 7 (for example, keys).

 The GGE block is located on the diaphragm 8 having a device 9 for quickly removing the GGE block from the housing. To maintain the dimensions of the replaceable GGE block, there is an insert 10 made of lightweight material. The mass of replaceable GGE blocks is constant, and in order to ensure the ballistic properties of the projectile, the replaceable GGE blocks are made with the same center of gravity relative to the front bottom and the axis of symmetry of the hull.

 To defeat targets of various types, for example, manpower, unarmored and lightly armored vehicles, the following options for GGE blocks are used (see table).

 In addition, replaceable GGE blocks can be combined, that is, consist of damaging elements of various masses. In order to increase the effectiveness of the projectile on flammable targets, the GGEs are covered with a layer of incendiary composition (for example, zirconium) with a thickness of 12 to 42 microns.

 An example embodiment of the invention in an artillery shell of a caliber of 120 mm for hitting unarmored vehicles.

 The shell of the projectile is made of high carbon steel 80G2S. Amazing finished elements of a cubic shape are made of a tungsten square bar with a side of 9 mm and tightly laid on the diaphragm in an amount of 500 pcs. GGEs are coated with zirconium 20 microns thick.

The volume inside the head cap is filled with a filler with a density of not higher than 5 kg / m ³ , for example polyurethane foam.

 The proposed projectile operates as follows. When setting the task of hitting targets at the projectile, the head cap 5 is removed and a replaceable block 4 with the required mass of the required mass is installed (replaced). The command for temporary installation before the shell rupture (flight time) is entered through the bottom receiver located in the fuse 3 using contact or non-contact methods. After a specified time, the fuse 3 firing chain fires, which initiates the main explosive charge 2. The targets are affected by the action of the GGE 4 and fragments of the body 1.

 When the explosive charge 2 is detonated, the shell 1 of the projectile is crushed into fragments that fly apart in the radial direction at a speed of 1000-1400 m / s and form an annular fragmentation field of destruction.

 At the same time, the head cap 5, the front bottom and the diaphragm 8 holding the GGE 4 are destroyed. Under the influence of detonation products, the ГПЭ 8 block receives acceleration in the axial direction, and under the action of centrifugal forces it also receives the radial component of the expansion, forming a flat circular field of destruction. This field moves in the direction of projectile flight and increases in radius.

скорости от воздействия продуктов детонации

и скорости от центробежного разлета

Угол разлета (φ) ГПЭ 4 определяется соотношением

При стрельбе на ударное действие в случае попадания в цель происходит контактное срабатывание взрывателя, и цель поражается осколками корпуса и фугасным действием ВВ. Блок ГПЭ в этом случае усиливает запреградное действие снаряда.The velocity of the GGE 4 is the sum of the velocity of the projectile at the time of detonation

speed from the effects of detonation products

and speeds from centrifugal expansion

The expansion angle (φ) of GGE 4 is determined by the ratio

When firing at an impact, in case of contact with the target, the fuse is contacted, and the target is struck by fragments of the body and the explosive action of explosives. The GPE block in this case reinforces the backward action of the projectile.

Claims (15)

 1. A fragmentation-beam projectile containing an explosive charge and a bottom fuse mounted in a housing with a front bottom, on which a multilayer block of densely laid ready-made striking elements and a head cap are installed, characterized in that the shell is made with the possibility of replacing a block of finished striking elements, and replaceable blocks are made up of elements of different weights.  2. The fragmentation-beam projectile according to claim 1, characterized in that the finished striking elements are made of steel or alloys based on tungsten.  3. The fragmentation-beam projectile according to claim 1, characterized in that the mass of ready-to-use striking elements is calculated for specific types of targets according to the criterion of the maximum probability of a single-shot hit. 4. The fragmentation-beam projectile according to claim 1, characterized in that the projectile is equipped with inserts made of material with a density of not higher than 5 kg / m ³ .  5. The fragmentation-beam projectile according to claim 1, characterized in that the head cap is made easily removable.  6. The fragmentation-beam projectile according to claim 1, characterized in that the finished striking elements are coated with a layer of incendiary composition with a thickness of 12 to 42 microns.  7. The fragmentation-beam projectile according to claim 1, characterized in that the finished damaging elements included in a separate unit have a mass of from 0.5 to 20 g. 8. The fragmentation-beam projectile according to claim 1, characterized in that the volume inside the head cap is filled with a filler with a density of not higher than 5 kg / m ³ .  9. The fragmentation-beam projectile according to claim 1, characterized in that the block of finished striking elements is placed on the diaphragm equipped with a device for quickly removing the block from the housing. 10. The fragmentation-beam projectile according to claim 1, characterized in that an insert of explosive material in the form of a straight truncated cone with a base radius R _d = (0.12 -0.14) d, with a smaller radius R _r = (0.08-0, l) d, with a height H = (0.07-0.09) d and facing a large base towards the bottom of the projectile.  11. The fragmentation-beam projectile according to claim 1, characterized in that the casing is made of high carbon steel.  12. The fragmentation-beam projectile according to claim 1, characterized in that the projectile equipment is made of a low-sensitivity composition, for example, triaminotrinitrobenzene.  13. The fragmentation-beam projectile according to claim 1, characterized in that the block of finished striking elements is equipped with a device that prevents it from turning relative to the shell of the projectile.  14. The fragmentation-beam projectile according to claim 1, characterized in that the replaceable unit of the finished striking elements has a layered or mixed stacking of striking elements of various masses.  15. The fragmentation-beam projectile according to claim 1, characterized in that the blocks of finished striking elements are made with the same center of gravity relative to the front bottom and the axis of symmetry of the hull.

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