RU2174210C1 - Multi-purpose warhead with transformable impact-action envelope - Google Patents

Abstract

FIELD: blasting equipment and arms equipment. SUBSTANCE: the warhead has a body made for deformation at a hit of an obstacle with formation of a cumulative facing and a jet at blasting, liquid or plastic explosive and a fuse. Formation of the cumulative envelope occurs as a result of variation of the body linear-angular parameters. EFFECT: provided cumulative action of a convention high-explosive warhead as a hit of an obstacle. 8 cl, 17 dwg

Description

 The invention relates to the field of explosive and armament technology, in particular, to engineering means for breaking holes in barriers, for remote crushing of oversized pieces of rock in the mining industry, as well as to means for destroying diverse targets, including armored.

 To penetrate the armor of military equipment, artillery shells, cumulative warheads of anti-tank missiles, cumulative armor-piercing shells, shell-forming charges, etc. are often used.

 The increased local effect of a charge explosion with cumulative recesses has been known for more than 100 years (Lavrentiev M.A. Cumulative charge and principles of its work / Advances in Math. Sciences. 1957, v. 1, pp. 41-66; Explosion Physics / Edited by K.P. Stanyukovich. - M .: Nauka, 1975).

 The most important value for practice is directed axial cumulation, which is realized by detonating charges having a recess of various shapes (hemisphere, cone, paraboloid, hyperboloid, etc.). Axial cumulation is associated with the formation and directional movement of a cumulative jet (CS).

 Part of the energy of the cumulative charge (SC) is pumped into the metal of the cumulative lining (KO) so that it is concentrated in a thin layer, which forms the SC. As a result of this, a significantly higher energy density in the CS is achieved than when the charge is detonated without CF.

 The "compaction" of energy, determined by the ratio of the diameter of the notch to the diameter of the CS, for charges without cladding is 4-5. For a charge with a metal KO, the “compaction” is much larger, because the diameter of the CS is much smaller than for charges without KO.

 The mass of the metal passing into the CS reaches ~ 20% of the mass of KO. The power of short-circuit is determined by the energy of detonation processes, and therefore, the content of high-energy components in the composition of the explosive (BB) of the charge, the homogeneity of the short-circuit in composition, the accuracy in initiating, the accuracy of the geometric dimensions of the charge, as well as the density, geometric dimensions, plastic properties and uniformity of the KO and other

 Measures to optimize the listed parameters in the manufacture of short circuit are associated with high labor costs, funds and materials. The use of expensive high-precision cumulative shells to defeat lightly armored vehicles is not always justified.

 A significant increase in efficiency can be achieved through the use of ammunition or warheads capable of hitting diverse targets, which will lead to a reduction in the range of weapons used. From this point of view, thin-walled ammunition equipped with liquid or plastic explosives is of great interest.

 Ammunition with a relatively thin "elastic" shell when interacting with obstacles changes its linear-angular parameters.

 Cumulative or high-explosive warheads for various purposes and various designs are known, the main purpose of which is to destroy or break through an obstacle with the formation of holes, to ensure maximum stop-action or, on the contrary, minimum, but pursuing the achievement of a certain hydrodynamic perfection of punched cavities (for the case of cumulative perforators - Friedlander L . I. Shot-blasting apparatus and its use in wells. - M.: Nedra, 1985).

 Known multi-purpose warhead, selected as a prototype (patent N 5591935A, USA, F 42 B 13/10).

 The warhead consists of a hull, a bursting charge, a detonator accelerator and a shock fuse, which contains two firing circuits for transmitting a detonation pulse to the accelerator. The first circuit is designed to initiate the accelerator when it hits a weakly protected target. The second fire chain is triggered when it hits a high-strength target, when the overloads upon contact with the target are large and the body is deformed without destruction in such a way that most of the bursting charge contacts the target surface, increasing the effectiveness of the warhead.

 The above warhead has disadvantages. In the presented form, to increase only high-explosive action at the target, the warhead is equipped with many elements, has a complex structure and, therefore, low reliability and high cost. In addition, it is not possible to break through a high-strength barrier (for example, armor), which is irrational from the point of view of using the energy of the explosion.

 The objective of the claimed invention is to increase the effectiveness of the warhead.

 The technical result consists in providing the cumulative effect of a conventional high-explosive warhead upon impact against an obstacle and is achieved by the fact that the warhead contains a housing in which liquid or plastic explosive and a fuse are placed, and the housing is capable of deformation upon impact against an obstacle with the formation of a cumulative lining and jets with subsequent detonation.

 Under this condition, when the warhead meets an obstacle, an elastoplastic change in the shape of the hull occurs in such a way that an annular cavity is formed, which collapses when an explosive is detonated to form an annular cumulative jet of shell material.

 For example, the front tapering part of the body can be made of a cylindrical-conical shape, while the rigidity of its conical part is less than the rigidity of a cylindrical one. The front tapering part can also be made in the form of two or more conical sections.

 It is known that the stiffness of a beam, pipe, shell, etc., which is the ratio of load to deflection or the magnitude of the force per unit of deformation, is directly proportional to the modulus of elasticity of the shell material and its thickness (cross-sectional area) and inversely proportional to the length of the shell. The modulus of elasticity characterizes the rigidity of the shell material under loads. The stiffness of the cross section of the body of this form is estimated by the moment of inertia. The product of these quantities characterizes the bending stiffness of the shell. In our case, the total stiffness of the cross section of the shell or casing, taking into account the mechanical and geometric properties of the structure, is determined as the product of the elastic modulus and the cross-sectional area.

 The change in the rigidity of the housing can be controlled by selecting the material of the cylindrical and conical parts of the front tapering part of the housing with the corresponding characteristics of strength and ductility, as well as by changing the wall thickness, for example, the wall of the front conical part can be made of variable thickness, or by applying to the front conical cases of rifts, corrugations, weakening grooves or, conversely, reinforcing protrusions, etc.

 Thus, the generators of the front tapering part on their outer and inner surface can be made in the form of a straight, broken or curved line with the condition that the stiffness (wall thickness) of the conical section of the shell is less than the stiffness (wall thickness) of the cylindrical part. The front conical part can also be made transversely corrugated to facilitate the process of plastic shaping of the cumulative cavity when it hits an obstacle. When the warhead is working with transversely corrugated shells, several cumulative jets are formed (by the number of corrugations).

 In special cases, the housing can be made with a "developed" front part, i.e. significantly different in diameter from the rest of the body.

 Significant differences can be in the strength and ductility of the material of the front and the rest of the body, which provides a difference in the stiffness of the parts of the body.

 For example, the housing can be made of a homogeneous material, but with different thicknesses of the walls of the cylinder and cone, and of dissimilar materials, but with such a prerequisite to achieve a technical result that the rigidity of the cylinder is greater than the rigidity of the cone.

 The power of the warhead is determined by the energy of the detonation processes, as well as the density, geometric dimensions, and plastic properties of the hull material.

 To increase the mass of metal passing into a cumulative stream, a coating of a material with a higher density than the density of the material of the front part, for example, at least 0.1 of the wall thickness of the conical part, can be applied to the outer surface of the front of the housing (cylindrical and conical) hulls, including those made of heavy metals and alloys (for example, tungsten-containing), which leads to an increase in the directional action of the cumulative jet. Also, an increase in the efficiency of formation of a cumulative jet is achieved by manufacturing a cylindrical and conical part of the body from a material denser (for example, steel) than the rest of the body made, for example, from aluminum.

 The process of deformation of the case depends on the overall mass parameters of the ammunition, the speed of approach to the obstacle and the characteristics of the fuse.

 To improve the conditions for the formation of a cumulative jet by providing sufficient time for deformation of the housing between the fuse and the housing, an elastic damper made of a thermoplastic material, such as polyethylene foam, or an inertial initiator (contactor) can be installed.

 When an ammunition with a damper hits an obstacle, the possibility of deformation of the fuse due to compression of the elastic damper is excluded.

In FIG. 1 shows a warhead with a fuse and damper;
in FIG. 2 shows the warhead at the stage of meeting with the obstacle;
in FIG. 3 - in the stage of deformation of the wall of the housing;
in FIG. 4 - at the stage of completion of the formation of the cumulative annular cavity;
in FIG. 5 - at the stage of explosion and formation of a cumulative jet;
in FIG. 6 - with a damper at the stage of meeting with an obstacle;
in FIG. 7 - with a damper at the stage of completion of the shaping of the cumulative annular cavity;
in FIG. 8 - shell of single curvature with rectilinear generatrices of the cone and with wall thickness decreasing towards the periphery;
in FIG. 9 - a shell of single curvature with rectilinear generatrices of the cone and with wall thickness increasing towards the periphery;
in FIG. 10 - shell single curvature with a broken generatrix on the inner surface of the cone;
in FIG. 11 - shell single curvature with a broken generatrix on the outer surface of the cone;
in FIG. 12 - shell double curvature with a curved generatrix of the outer surface of the cone;
in FIG. 13 - shell double curvature with a curved generatrix of the inner surface of the cone;
in FIG. 14 - shell double curvature with a groove on the outer surface;
in FIG. 15 - shell single curvature with a groove on the inner surface;
in FIG. 16 - transverse corrugated shell with two corrugations;
in FIG. 17 - transversely corrugated shell with one corrugation, where r is the radius of conjugation of a rectilinear and curved section of the body, h is the wave height of the corrugation of the shell.

 A multi-purpose warhead with a transformable shell of the shock according to an independent claim consists of a body 1 made with the possibility of deformation upon impact against an obstacle with the formation of a cumulative lining and stream during the next blast, in which a fuse 2 and a liquid or plastic explosive 3 are placed. the tapering part of the body can be made in the form of a conical part 4, turning into a cylindrical part 5, while the rigidity of the conical part 4 is less than the rigidity of the cylindrical part 5.

 The warhead works as follows.

 When the warhead hits the obstacle 7 (Fig. 2) due to the loss of stability of the shell under the action of axial forces, the front tapering part of the casing 1 is deformed, in which the fuse 2 and the liquid or plastic explosive 3 are placed.

 The contact forces arising between the plastic or liquid explosive and the body can be so significant that they carry the body along with the contents forward and provide the process of changing the shape of the conical-cylindrical front of the body to form a shell of alternating curvature - cumulative lining 8. Elastoplastic deformation of the shell occurs in accordance with the specified characteristics of strength and stiffness of the walls of the housing, in such a way that provides a boundary effect, which consists in the absence deformation of the front cylindrical part 5 (dashed in FIG. 1) and the front of the cone 4, and the remainder of the cone 4 and the front portion of the cylindrical wall of the body shown in FIG. 1 dash-dotted line.

 When fuse 2 is initiated, a detonation wave propagates through the explosive 3, and when it passes through the cumulative lining 8, an annular cumulative jet 9 is formed, whose energy is sufficient to hit the barrier 7 with cutting down its part 10 and penetration of the explosion products 11 beyond the barrier 7.

 The shaping of the cumulative cavity from the front cylindrical-conical part of the housing depends on the rigidity of the shell of the head part, which can be changed by using various combinations of the profile of the outer and inner surfaces of the cone, as illustrated in FIG. 8-11 - for shells of single curvature, FIG. 12, 13, 14 - for shells of double curvature. The same goal is achieved through grooves and grooves - FIG. 14, 15, rifts and valleys of FIG. 16, 17. The latter are generally summarized by the notion of a transversely corrugated shell. When the warhead operates with such shells, several cumulative jets are formed (according to the number of corrugations).

 The linear-angular parameters of the resulting cumulative cavity and, therefore, the penetration ability of the warhead depend on the cross-sectional profile of the wall of the front of the hull and the characteristics of the material. The optimal combination of these parameters ensures the maximum penetration ability of the warhead.

 When you hit an obstacle 7 ammunition with an elastic damper 6 (Fig. 6) provides improved conditions for the formation of cumulative lining, and consequently, the cumulative jet.

 Thus, it is the execution of the front part with a cylindrical-conical shape, in the wall of which the distribution of radial and axial deformations is laid by establishing certain ratios of the taper and wall thickness, the depth of the grooves and the height of the protrusions, as well as, for example, the relationship between the corrugation wave height h of the shell and the radius r of conjugation of the straight sections between themselves (Fig. 17) provide for the formation of a cumulative cavity during the interaction of the warhead with an obstacle.

 The main condition for the normal course of the process of forming the cumulative recess is that the rigidity of the conical section of the shell is less than the rigidity of the cylindrical part.

Claims (8)

 1. A multi-purpose warhead with a transformable shell of shock, including a housing in which an explosive and a fuse are located, characterized in that liquid or plastic explosive is selected as the explosive, and the housing is capable of deformation upon impact against a barrier to form a cumulative cladding and spray with subsequent blasting.  2. Multipurpose warhead according to claim 1, characterized in that the front tapering part of the hull is cylindrical-conical in shape, while the stiffness of its conical part is less than the stiffness of the cylindrical.  3. Multipurpose warhead according to any one of claims 1 and 2, characterized in that the wall of the front conical part of the hull is made of variable thickness.  4. Multipurpose warhead according to claim 2 or 3, characterized in that the outer surface of the front conical and cylindrical parts of the body is coated with a material with a higher density than the density of the material of the front part.  5. Multipurpose warhead according to claim 4, characterized in that the coating thickness is at least 0.1 of the wall thickness of the conical part of the hull.  6. Multipurpose warhead according to any one of claims 2 to 5, characterized in that the front conical part of the hull is transversely corrugated.  7. Multipurpose warhead according to any one of claims 1 to 6, characterized in that the fuse is equipped with an inertial initiator.  8. Multipurpose warhead according to any one of claims 1 to 6, characterized in that an elastic damper is installed between the fuse and the body.

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