RU2327948C2 - Fragmentation beam projectile "otroch" - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: inventive projectile relates to a multi-purpose high-explosive ammunition producing a fragment beam in both the axial and the lateral directions. The projectile comprises a one-piece casing with a nose portion and an explosive charge having a fragmentation block disposed in front of said explosive charge, a detonator disposed in the middle portion of said explosive charge, and a time/contact nose fuze being electrically connected with said detonator. The nose portion of the casing has a conical or ogival shape. The fragmentation block embraces the nose portion of the casing outside, and the detonator is fitted with a safety device and an adjustable delay mechanism.

EFFECT: enhancement of the destructive capability of the projectile during its penetration into obstacles and the safety of its use.

11 cl, 8 dwg

Description

The invention relates to multipurpose high-explosive fragmentation ammunition having both axial and circular fields of destruction.

Known fragmentation-beam shells containing a shell with an explosive charge (EXPLOSIVES), a fragmentation block located in front of the explosive charge, a detonator located in the middle part of the charge and a head fuse connected by a central tube to the detonator (US Pat. DE 19648355 AI Germany).

The main disadvantage of the projectile is the inability to penetrate strong obstacles (semi-frozen and frozen soils, brick and concrete walls, etc.), due to the low strength of the thin-walled design of the head. An increase in the wall thickness of the head part in this design would lead to the loss of a significant part of the damaging elements of the fragmentation block and the destruction of the axial flow. Another disadvantage is the danger of spontaneous detonation of a projectile during firing due to the high pressure developed on the contact surface of the fragmentation explosive fragment charge.

The present invention addresses these drawbacks.

The technical solution consists in the fact that in a fragmentation-beam projectile containing a body with a monolithically made head part and with an explosive charge having a fragmentation block located in front of the explosive charge, the detonator located in the middle part of the explosive charge, the head fuse is trajectory contact type, electrically connected to the detonator, the head of the body is conical or animated, the fragmentation block covers the head of the body from the outside, while the explosion l made electronically, and is equipped with a detonator safety device and node controlled deceleration.

The location of the fragmentation block outside its body, the head of which is made conical or animated, allows for increased damage when penetrating obstacles, and also increases safety during operation of the projectile. In this case, it is necessary that the fuse be electronic, and the detonator must be equipped with a safety mechanism and an adjustable deceleration unit.

The invention is illustrated by drawings, where

figure 1 is a diagram of a shell for a smoothbore tank gun; figure 2 - 3 - embodiments of the head of the shell; 4 is a diagram of the action of the projectile on a solid barrier.

The general scheme of the projectile for a smoothbore tank gun is shown in figure 1. The projectile comprises a housing 1 with a monolithic head part 2 of a conical or animated shape filled with a charge of explosive 3. A fragmentation unit 4 with an electronic head fuse 5 of trajectory-contact action adjoins the head part of the body. The fuse includes a head contact assembly 6, a receiver 7 and is connected by a central tube 8 passing through the axial channel 9 located in the head of the housing to the detonator of the detonation assembly 10. Electrical conductors 11 are located inside the detonator. The detonation assembly 10 includes a detonator 12, a safety mechanism 13 and an adjustable deceleration assembly 14. At the rear of the housing there is a screw bottom 15 to which a stabilizer block 16 is connected.

The fragmentation block 4 is made in the form of a composite structure containing ready-made striking elements (GGE) made of steel or heavy alloys based on tungsten, and a binder material. The GGEs are predominantly made in a form that ensures their tight packing in a block, for example, in the form of cubes, parallelepipeds, hexagonal prisms. In the embodiment shown in figure 2, the fragmentation unit is equipped with a frame made, for example, in the form of a set of diaphragms 17 connected to the Central tube. In the embodiment of FIG. 3, in front of the fragmentation block is a thin-walled ballistic cap 18, in front of which a head fuse is mounted. In the embodiments of FIGS. 1 to 3, the fragmentation block can be strengthened by winding a thread 19 or tape made, for example, of fiberglass or carbon material on its lateral surface.

The fragmentation block may be provided with a thin-walled shell 20 (Fig. 4) made of light alloy or composite material. Figure 5 shows the design of a fragmentation unit equipped with both a diaphragm frame and an outer shell.

In the design shown in Fig.6, the fragmentation block is made in one piece (without a channel), the fuse is installed under the block in the head of the body, and the receiver 7, which is also a contact node, is located on the side surface of the projectile and represents a ring isolated from the body, connected with a fuse electrical conductor 21. In Fig.7 presents the same design with a fragmentation unit provided with a frame 17 and a ballistic cap 18.

Another advantage of the location of the fragmentation block external to the housing is the ability to perform it interchangeably. The use of removable blocks with various designs, including those with different masses of gravitational explosives (for example, with masses of gravitational reserves of 1-2 g for the destruction of manpower or with a mass of 3-5 g for the destruction of unarmored vehicles, or with a mass of 20- 30 g for hitting lightly armored targets), with different scattering angles due to the shape of the block, inserts in it, etc., with different properties of the GGE, for example with enhanced incendiary effect, while the fragmentation block and the casing are equipped with a device that allows replacing the block in the process e operation.

The action of the projectile is as follows. Before firing through the receiver of the installation 7, the installation is introduced to the type of action, and when using a temporary fuse also the flight time of the projectile before the gap.

When fired, the inertial load from the pressing mass of the fragmentation block is perceived by the head of the body and is not transferred to the explosive charge. Taking in the design of the prototype the mass of the unit is 2 kg and the overload of 20,000, we obtain a force acting on the front surface of the charge of 40 tons, which can lead to contact crushing of the explosive charge, its destruction and ignition, and ultimately to the explosion of the projectile in the barrel. After the departure of the projectile from the bore and removal of overloads, the safety mechanism 13 is released.

The projectile is multifunctional and, depending on the installation, has the following types of actions:

- trajectory gap on approaching the target (at a pre-empted point) with the target being hit by the axial flow of the GGE;

- trajectory gap above the target with the defeat of the target by a circular field of fragments of the body;

- shock ground rupture with installation on instant (fragmentation) action;

- shock ground rupture with installation on high-explosive fragmentation effect (low deceleration);

- shock ground rupture with installation on a penetrating high-explosive action (large deceleration).

When approaching the projectile at the calculated point, the fuse delivers an electrical signal to detonate the detonator 12. The action when installing the fuse on the impact fragmentation effect is carried out in a similar way.

When firing with the installation at small or large slowdowns and with a strong barrier, destruction of the fragmentation block may occur together with the fuse and protruding part of the central tube protruding from the body (Fig. 8). At the same time, the GGE of the fragmentation block, flying in radial directions, creates an additional damaging effect in front of the obstacle, and the GGE, penetrated beyond the obstacle, provide a backward action.

The strength of the fragmentation block during firing is ensured, on the one hand, by the high mechanical properties of the composite fragmentation block, and on the other, by the presence of a power frame, external winding, or external thin-walled shell.

The thickness and material of the shell are selected from the condition of its stable destruction during explosive throwing of the block.

Claims (11)

1. A fragmentation-beam projectile comprising a body with a monolithically made head part and with an explosive charge, having a fragmentation block located in front of the explosive charge, a detonator located in the middle of the explosive charge, a trajectory-contact head fuse electrically connected to detonator, characterized in that the head part of the body is conical or animated, the fragmentation block covers the head part of the body from the outside, while the fuse is made of electric and the detonator is equipped with a safety mechanism and an adjustable deceleration unit. 2. The projectile according to claim 1, characterized in that the fuse is installed in front of a fragmentation unit made with an axial channel in which a central tube is placed with an electric conductor connecting the fuse to the detonator. 3. The projectile according to claim 2, characterized in that the fragmentation unit is equipped with a skeleton made in the form of a set of diaphragms attached to the central tube. 4. The projectile according to claim 1, characterized in that in front of the fragmentation unit is a thin-walled ballistic cap, and the fuse is mounted in front of the ballistic cap. 5. The projectile according to claim 1, characterized in that on the side surface of the fragmentation unit, the thread or tape is made of fiberglass or carbon material. 6. The projectile according to claim 1, characterized in that the fragmentation unit is provided with a thin-walled shell made of light or composite material. 7. The projectile according to claim 1, characterized in that the fragmentation unit is made without a channel, while the fuse is installed under the unit in the head of the body, and the fuse receiver, which is also a contact node, is located on the side surface of the projectile and represents a ring isolated from the body connected to the fuse by an electrical conductor. 8. The projectile according to claim 1, characterized in that the fragmentation block is made of ready-made striking elements glued together with a binder. 9. The projectile of claim 8, characterized in that the finished striking elements are made in a form that ensures their tight packing in the block. 10. The projectile of claim 8, characterized in that the finished striking elements are made of steel or heavy alloys based on tungsten. 11. The projectile according to claim 1, characterized in that the fragmentation unit is removable and interchangeable with various designs of both the shape of the unit and the finished striking elements and is equipped with a device that allows it to be replaced during operation.

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