RU2559377C1 - Fragmentation part of fragmentation and particle beam shell - Google Patents

Abstract

FIELD: weapon and ammunition.

SUBSTANCE: fragmentation part of fragmental and particle beam shells, generating the striking elements, contains the housing implemented in the form of multilayered annular set along axis of which an extended explosive charge, a device for dispersion of striking elements, and a contact and trajectory detonator are installed. The annular layers of the fragmentation part are implemented in the form of cylindrical spirals. Cross section of, at least, one spiral, mainly of all, is profiled. At least, one spiral of annular layer, preferably all, is made with pre-set pitch. In gaps between turns the ready striking elements are installed. The width of the named striking elements is equal to the width of gaps between spiral turns.

EFFECT: increased efficiency of shell.

17 cl, 7 dwg

Description

The invention relates to ammunition, in particular to fragmentation-beam projectiles with time-divided formation of axial and circular fragmentation fields.

Known fragmentation-beam projectile containing a housing with an explosive charge and a detonator located outside the housing on the same axis as a fragmentation unit that generates striking elements of the same mass, a device for dispersing the striking elements and a contact trajectory fuse, while the shell of the fragmentation unit is made in the form a multilayer set of rings, the axis of which has an elongated charge equipped with wedge-shaped cumulative recesses (RF patent for the invention No. 2464525, IPC: F42В 12/20, F42В 12/28, F42В 12/32 - prototype).

The specified fragmentation-beam projectile is used as follows.

At an anticipated point in the trajectory in front of the target, the fuse detonates the cumulative charge. Cumulative “knives” cut through the shell of the fragmentation block, thus forming elongated fragments that receive a relatively small radial velocity. During expansion, a disk-shaped field of fragments is formed, moving along the axis (axial flow). The shell of the projectile with a charge of explosive (BB) moves further and, depending on the installation of the fuse, detonation occurs either, with a flat path, above the target, or, with a hinged path, at the moment of impact on the ground. The result is a combined effect on the target of the axial flow of fragments of the fragmentation block and the circular field of fragments during crushing of the shell of the shell.

When fired, the ring design of the fragmentation block provides its necessary strength, which distinguishes it from fragmentation blocks from ready-made striking elements.

The main disadvantages of this projectile is that the rings installed coaxially in each other, forming a multilayer cylindrical set, when the shell is detonated, they are destroyed arbitrarily, with the formation of fragments of different mass and sizes, which leads to a decrease in the damaging effect of the projectile.

The objective of the invention is to remedy these shortcomings and create a fragmentation-beam projectile with a fragmentation unit mounted outside the shell of the projectile, collapsing in the explosion with the formation of fragments of approximately the same mass and size, increasing the manufacturability of the projectile.

The solution to this problem is achieved by the fact that in the proposed fragmentation unit of the fragmentation-beam projectile generating the striking elements, comprising a body made in the form of a multilayer ring set, an elongated explosive charge, a dispersion element of the striking elements and a contact-trajectory fuse are installed along its axis the invention, the annular layers of the fragmentation block are made in the form of cylindrical spirals, and the cross section of at least one spiral, mainly all, is made non-profiled, while at least one spiral of the annular layer, preferably all, is made with a given step, while ready-made striking elements are installed between the turns, the width of these striking elements being equal to the width of the gap between the turns of the spiral.

In an embodiment, the inner and outer layers of the fragmentation block are made of continuous rings, while the intermediate layers are made in the form of cylindrical spirals.

In an embodiment, the annular layers of the fragmentation block are made in the form of a spiral with a generatrix of a given shape.

In an embodiment, the turns of said spirals interact with each other with their end surfaces.

In an embodiment, the turns of the block are made in the form of Archimedean spirals, and the turns are made close to each other.

In an embodiment, the turns of the block are made in the form of Archimedean spirals, and the turns are made with a gap, while ready-made striking elements are installed in the gap between the turns, the overall dimensions of which correspond to the thickness of the spiral and the width of the gap between the turns.

In the embodiment, the fragmentation block is made in the form of Archimedean spirals, while the spiral turns have a variable thickness in the radial direction, decreasing from the center to the periphery.

In an embodiment, the cross section of the spiral is made in the form of a parallelogram.

In an embodiment, the cross section of the spiral is made in the form of a square.

In an embodiment, the cross section of the spiral is made in the form of a triangle.

In an embodiment, the cross section of the spiral is made in the form of a zigzag.

In an embodiment, at least on one surface, preferably on all surfaces of at least one spiral, preferably on all spirals, transverse corrugations are applied.

In an embodiment, the cross section of the spiral is made in such a way that after installing the spiral, part of the cylindrical surface of the subsequent turn interacts with the cylindrical surface of the previous turn, while the thickness of the layer of the coil is equal to the thickness of the spiral.

In an embodiment, the spirals are installed in such a way that the turns of each subsequent cylindrical spiral are located with an offset preferably equal to half the width of the turn, relative to the turns of the previous spiral.

In an embodiment, the cylindrical spirals forming the layers of the fragmentation block have different thicknesses in the radial direction with a decrease from the center to the periphery.

In an embodiment, the inner and outer annular layers of the fragmentation block are made of solid rings installed with a predetermined pitch, while ready-made striking elements are installed in the spaces between the rings, the width of these striking elements being equal to the width of the gap between the rings.

In an embodiment, the elongated charge is provided with cumulative recesses.

The fragmentation block can be installed both in front and behind the shell of the projectile. For shells of smooth-bore tank guns equipped with stabilizing plumage, the installation of a fragmentation block in the front of the shell is preferable; for shells of rifled field guns stabilized by rotation, the installation of a fragmentation block in the rear of the shell is preferred.

The technical result of the invention is to increase the power of artillery shells. The implementation of the annular layers of the fragmentation block in the form of cylindrical spirals allows, in comparison with the fragmentation block made of rings, to increase the manufacturability of the projectile while maintaining the strength of the block in the radial direction. In the case of applying deep corrugation to the surface of the spiral, significantly less detonation energy of the explosive is required for crushing the spiral, which allows either to increase the affected area with equal overall charge characteristics, or to increase the mass of fragments by increasing the number of layers of the fragmentation block.

In addition, in the process of winding the spiral, you can give the fragmentation unit the desired shape, both internal and external surfaces.

The spiral can be made of ductile steel with a given step equal to the size of the finished striking elements (GGE) and with a height equal to the height of the GGE installed between the turns, while the GGE can be made of carbide material, for example, tungsten.

The implementation of a spiral profiled with a cross section in the form of a rhombus / parallelogram / square / triangle and other geometric figures with previously applied stress concentrators - corrugations allows you to guaranteedly receive fragments of a given mass and geometric shape, because the destruction of the spiral will occur in places of application of stress concentrators. At the same time, the manufacturability of the fragmentation block is ensured, since performing corrugations on a metal spiral is much simpler and cheaper than performing corrugations on solid rings, especially on their inner surface.

The invention is illustrated by drawings, where in FIG. 1 shows a projectile with a front-mounted fragmentation unit; in FIG. 2 - a shell with a rear location of the fragmentation unit; in FIG. 3 - projectile with pre-detachable fragmentation unit; in FIG. 4, 5 - embodiment of the fragmentation block; FIG. 6 is an embodiment of a fragmentation block with filling the gaps between the turns of the GGE; FIG. 7 is a view of a general fragmentation field of a projectile.

The fragmentation block is considered as part of a fragmentation-beam projectile.

The projectile consists of a casing 1 with an explosive charge 2 and a detonator 3. In the rear of the casing there is a screw bottom 4 with a stabilizer that is attached to it. In the front of the projectile there is a fragmentation unit 5 made in the form of several layers of a spiral 6. Inside the fragmentation unit 5 an elongated cumulative charge 7 is installed. In front of the fragmentation unit 5 there is a casing 8 in which a head contact-trajectory fuse 9 is placed. Between the cumulative charge 7 and detonator 3 mounted moderator 10.

In an embodiment, the fragmentation unit 5 is located in the rear of the shell body 1. In the bottom of the projectile 11 mounted contact trajectory fuse 12.

In an embodiment, the projectile is equipped with a pyrotechnic charge of compartment 13 with an igniter 14 connected to the fuse.

In an embodiment, the elongated cumulative charge of fragmentation of the fragmentation block 5 consists of an elongated explosive charge 15, along which wedge shaped cumulative linings 16 are formed. The charge can be provided with an axial tube 17. The gap between the charge and the inner surface of the fragmentation block is selected from the condition for the development of a full wedge-shaped cumulative jet, providing destruction of the fragmentation block along the generatrix.

In an embodiment, the explosive charge fills the entire internal volume of the fragmentation block. The formation of damaging elements (PE) of a given crushing is ensured by corrugations deposited on the rings and spirals of the fragmentation block.

In an embodiment, ready-made striking elements 18 are located between the turns of the spiral 6.

The use of the proposed fragmentation block is considered using an example of a fragmentation-beam projectile with the proposed fragmentation block.

At the lead point of the trajectory, in front of the target, fuse 9, in the structure shown in FIG. 1, or 12, in the structure shown in FIG. 2, undermines the charge 7 of the fragmentation block 5. In this case, the cumulative “knives” destroy the shell of the fragmentation block 5 with the formation of elongated fragments that receive a relatively small radial velocity. When the fragments fly apart, a disk-shaped field 19 is formed, moving along the axis (axial flow) (Fig. 7). The shell 1 of the projectile with the explosive charge moves further and, depending on the installation of the fuse, detonation occurs either, with a flat path, above the target, or, with a hinged path, at the moment of impact on the ground. The result is a combined effect on the target of the axial flow of the fragments 19, which is formed when the fragmentation block 5 is detonated, and the circular field of the fragments 20, when the shell 1 of the projectile is crushed.

The action of the projectile shown in FIG. 3 is carried out as follows. At a proactive point in the trajectory, the fragmentation block 5 is fired using the pyrotechnic charge of the compartment 13. After the projectile is removed from the fragmentation block 5 at a distance that excludes the impact of the charge 7 explosion on the projectile, the cumulative charge 7 is triggered, and then the shell itself is undermined.

Designs with a rear arrangement of the fragmentation block and a monolithic design of the head of the hull allow, if necessary, to use the projectile as concrete-piercing. In this case, the fragmentation of the fragmentation block is carried out behind the barrier, which significantly increases the backward action.

The multilayer design of a fragmentation block made of spirals or rings and spirals is more resistant to the forces arising from firing, in contrast to fragmentation blocks from ready-made striking elements and solid rings due to the connection between the spiral rings, it is more technologically advanced, in contrast to fragmentation blocks from rings, and when applying corrugations, it allows to increase the mass of the fragmentation fragmentation charge, by eliminating cumulative notches and the gap between the charge and the internal surface of the fragmentation unit, or increase s fragmentation block number of layers while maintaining the outer diameter of the charge.

Using the proposed technical solution will allow you to create a fragmentation-beam projectile with a fragmentation unit mounted outside the shell of the projectile, collapsing in the explosion with the formation of fragments of a given crushing.

Claims (17)

1. The fragmentation block fragmentation-beam projectile, generating striking elements, comprising a housing made in the form of a multilayer ring set, the axis of which has an elongated explosive charge, a dispersion device of striking elements and a contact trajectory fuse, characterized in that the ring layers of the fragmentation block made in the form of cylindrical spirals, and the cross section of at least one spiral, mainly all, is profiled, with at least one spiral count tsevogo layer, preferably all made at a predetermined pitch, while the interstices between the turns set ready submunitions, the submunitions width of said gap is equal to the width between the turns of the helix. 2. The fragmentation block according to claim 1, characterized in that the inner and outer layers of the fragmentation block are made of continuous rings, while the intermediate layers are made in the form of cylindrical spirals. 3. The fragmentation block according to claim 1, characterized in that the annular layers of the fragmentation block are made in the form of a spiral with a generatrix of a given shape. 4. The fragmentation block according to claim 1, characterized in that the turns of the said spirals interact with each other with their end surfaces. 5. The fragmentation block according to claim 1, characterized in that the turns of the block are made in the form of Archimedean spirals, and the turns are made close to each other. 6. The fragmentation block according to claim 1, characterized in that the turns of the block are made in the form of Archimedean spirals, and the turns are made with a gap, while ready-made striking elements are installed in the gap between the turns, the overall dimensions of which correspond to the thickness of the spiral and the width of the gap between the turns. 7. The fragmentation block according to any one of claims 5 or 6, characterized in that the fragmentation block is made in the form of Archimedean spirals, while the spiral coils have a variable thickness in the radial direction, decreasing from the center to the periphery. 8. The fragmentation block according to claim 1, characterized in that the cross section of the spiral is made in the form of a parallelogram. 9. The fragmentation block according to claim 1, characterized in that the cross section of the spiral is made in the form of a square. 10. The fragmentation block according to claim 1, characterized in that the cross section of the spiral is made in the form of a triangle. 11. The fragmentation block according to claim 1, characterized in that the cross section of the spiral is made in the form of a zigzag. 12. The fragmentation block according to claim 1, characterized in that at least on one surface, preferably on all surfaces of at least one spiral, preferably on all spirals, transverse corrugations are applied. 13. The fragmentation block according to claim 1, characterized in that the cross section of the spiral is made in such a way that after installing the spiral, part of the cylindrical surface of the subsequent turn interacts with the cylindrical surface of the previous turn, while the thickness of the layer of the coil is equal to the thickness of the spiral. 14. The fragmentation block according to claim 1, characterized in that the spirals are mounted in such a way that the turns of each subsequent cylindrical spiral are located with an offset preferably equal to half the width of the turn, relative to the turns of the previous spiral. 15. The fragmentation block according to claim 1, characterized in that the cylindrical spirals forming the layers of the fragmentation block have different thicknesses in the radial direction with a decrease from the center to the periphery. 16. The fragmentation block according to any one of claims 1 or 14, characterized in that the inner and outer annular layers of the fragmentation block are made of solid rings installed with a given step, while ready-made striking elements are installed between the rings, the width of these striking elements equal to the width of the gap between the rings. 17. The fragmentation block according to claim 1, characterized in that the elongated charge is provided with cumulative recesses.

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