PL205007B1 - Remote striking head for the shot explosion forming - Google Patents

Description

The subject of the invention is a remote destruction warhead for explosive formation of a single missile, intended for the destruction of armored fighting vehicles, in particular tanks.

Cumulative charges exhibit a directional effect, the effects of which strongly depend on the design of the entire head. The cavity in the explosive charge can be of various shapes. Most often it is a cone, hemisphere or low-height spherical ball. Covering the surface of the cavity with an insert made of metal, glass, ceramics or other solid material significantly increases the effect of the directional action of the shaped charge.

Conical inserts with a high height, i.e. with a small opening angle, and hemispherical inserts generate cumulative jets with a front speed of 4 to 8 km / s. In contrast, low-height inserts generate a few quick debris, or in some cases a solid body, known as an explosive projectile, abbreviated to EFP. The speed of such a projectile can reach a value in the range of 2-3 km / s.

In the known head for explosive projectile molding, made of a cylindrical housing, an end cap with an axial bore, an inertial diaphragm and an insert holding the charge of the explosive placed in the housing, a fuse mounted in the axial opening of the bottom initiates the detonation of the explosive. The system of forming the front of the detonation wave, consisting of a detonator and an explosive filling the inner area of the bottom together with the detonation lens, is used to properly shape the front of the detonation wave. In the case of point initiation, the shape of the detonation wave front is approximately a sphere whose center coincides with the point of initiation of detonation. On the other hand, the applied detonation lens allows to obtain a toroidal shape of the front of the detonation wave, which facilitates the appropriate shaping of the projectile. The shape of the resulting projectile strongly depends on the structure of the explosive, the shape of the insert and the location of the point of initiation of detonation.

The description of the known head for explosive forming of a projectile does not specify the effect of fragmentation of the periphery of the insert on the stability of the projectile on its trajectory. Fragmentation of the periphery of the insert, causing bullet rotation, is an obvious result of fixing and fixing the insert in the housing by means of the annular shoulder of the housing, and this fragmentation in this case may be a minor factor.

There is known a shaped explosive with a wave shaping detonation lens described in US Patent No. 5,565,644. The head, which includes an all-round explosive charge and a detonating lens, has a casing with an elliptical inner wall, which is in fact symmetrical with respect to the longitudinal symmetry axis of the head. The point of initiation of detonation, i.e. the fuse, is located axially in the lower part of the housing. The explosive is disposed between the elliptical inner wall of the housing and the insert, which insert may have the shape of a hemisphere, paraboloid, ellipsoid, pear or phono tube. The insert material may be copper, depleted uranium, tungsten, tantalum, or other material. The insert is connected to the inner wall of the housing with a ring. A convex-convex lens is placed near the concave top of the inner wall of the housing, forming a detonation wave front forming system together with the fuse.

The description of a shaped explosive with a wave-shaping detonation lens does not specify the impact of the fragmentation of the liner periphery on the stability of the projectile on its trajectory. Fragmentation of the periphery of the insert, resulting in bullet rotation, is an obvious result of fixing and fixing the insert in the housing by means of the shoulder collar of the housing, and this fragmentation in this case may be a minor factor.

A system for producing shaped explosives is known, as is described in US Patent No. 4,982,667. The system comprises a casing with a cylindrical inner surface, which casing is filled with explosive material and sealed on the front side with an insert and on the rear side with a bottom. The insert has the shape of a concave disc with a small wall thickness and is made of, for example, steel, copper or heavy metal. The inlay has a non-homogeneity consisting in a wavy distortion of the disc. The outer surface of the casing is in the shape of a regular polygon, e.g., hexagonal, octagonal, so that at the corners of the outer surface of the casing, the walls have the greatest thickness. An axially disposed fuse is located in the bottom of the housing, the individual detonation points of which being parts of the fuse having different ignition energy or different ignition delay are arranged symmetrically near the circumferential edge of the cap. After the detonation wave hits, initially the disc is bent in the center and later

The deformation of its undulating distortions takes place in the final phase, forming single, regularly spaced folds in the final stage, acting as a means of stabilizing and stabilizing the projectile.

The description of the production of shaped explosive projectiles does not specify the effect of fragmentation of the periphery of the regularly spaced disc folds on the stability of the projectile on its trajectory. The fragmentation of the disc folds, which causes the projectile to rotate, is an obvious result of the fixing and fixing of the disc in the housing by means of the annular collar of the housing, and this fragmentation by means of stiffening means may be a minor factor in this case.

There is also known a cumulative cartridge with a directional explosion effect, described in Polish patent specification no. 140102. The cumulative cartridge comprises a housing, an explosive housed in this housing, a fuse placed in the bottom of this housing, and an insert having the shape of an extruded cone, placed in the front part of the housing. The casing of the high-pressure cartridge and the metal insert are precisely centered on a common axis of symmetry on which the fuse is also located. The cone is varied and mold extruded directly from the hot-rolled pure copper sheet, without allowing the sheet to cool significantly after hot rolling. The differentiation of the cone is that the convexity of the cone wall, the thickness of which is uniform throughout the entire cone, measured from the wall of a straight cone with the same cone angle, is smaller than the thickness of the rest of the cone wall and is approximately half the thickness of the rest of the cone. The shape of the housing, near its face, is cylindrical and then tapers to become a frusto-conical shape. Due to the shape of the housing and the shape of the copper cone, the angle of impact of the detonation wave on the surface of the copper cone is almost constant, and the differences in acceleration between parts of the mass of the hollow cartridge are minimal, with the detonation wave of this cartridge being quasi-spherical.

The description of the cumulative cartridge with a directional explosion effect does not specify the impact of fragmentation of the liner periphery on the cartridge stability on its trajectory. Fragmentation of the liner periphery, causing the cartridge to rotate, is an obvious result of fixing and retaining the liner in the housing with the annular collar of the housing, and this fragmentation in this case may be a minor factor.

There is also a remote destruction head for explosive formation of missiles, generating an explosively formed, uniform projectile or several high-energy fragments, described in the Polish application, marked with the number P.351049. The general structure of the remote destruction warhead for explosive projectile formation is as follows. The housing has the shape of a cylinder, with in its front part a ring catch flange, which determines the position of the insert, seated inside the housing, the insert has the shape of a low-height spherical bowl and is made of copper, iron "ARMCO, or tantalum. The insert is centrally located with its apex pointing towards the center of the head. In the rear part of the housing, there is a circular bottom with a two-stage cylindrical surface, adhering closely with its external cylindrical surface of large diameter to the internal cylindrical surface of the housing. The position of the bottom, located centrally inside the housing, is fixed by a pressure ring pressed between the internal cylindrical surface of the housing and the external cylindrical surface of the bottom. An explosive is placed inside the casing between the insert and the bottom. The housing is made of metal, preferably aluminum alloys, or it can be composite or composite metal. In the case where the warhead generates an explosively formed homogeneous projectile, the casing of this warhead is made of uniform duralumin. The casing, made of duralumin, allows the pressure of the detonation products to be sustained in the first phase of the generation of an explosively formed homogeneous projectile, then it tears into small parts with minimal fire power. The first stage of detonation of the explosive is caused by the ignition means, which are the first and second detonators. The first detonator is located near the tip of the insert on the longitudinal symmetry axis of the housing, while the second detonators are located radially and seated in the bottom near its outer circular edge. As a trigger directly acting on the ignition means, i.e. all fuses, an external decision block is used, the first output of which is connected to the first fuse and the second output is connected in parallel to the second fuses. In the case of the generation of an explosively formed, uniform projectile by the warhead, the detonation of the explosive is performed by second detonators, whereby three phases of pressure distribution in the products of detonation of the explosive can be selectively distinguished. In the first selective phase of pressure distribution in the detonation products, the explosive, that is 10 μs from the moment of detonation initiation, distinguishes: the detonation wave front; initial pressure at the front of the detonation wave; very high growth

Pressure at the front of the detonation wave, caused by cumulative effects on the longitudinal axis of symmetry of the casing, thus on the axis of the explosive charge; the front of the shock wave reflected from the axis of the explosive charge and the front of the shock wave reflected from the housing. In the second selective phase of pressure distribution in the detonation products of the explosive, i.e. 15 μs from the moment of detonation of the explosive material, the pressure distribution reaches the resulting apogee, while distinguishing between the overlapping fronts, i.e. the front of the detonation wave, the front of the shock wave reflected from the axis explosive charge and the front of the shock wave reflected from the housing is very difficult. In the third selective phase of pressure distribution in detonation products, that is 20 μs from the moment of detonation of the explosive material, the pressure distribution is already very even and has three distinctive fronts: a quasi-spherical front; ring-shaped front and bell-shaped front with a short generatrix and a large opening angle. The quasi-spherical pressure front first acts on the tip of the insert, and then on the inner, apical part of the surface of this insert with a slight delay, resulting from its convexity, forming its rounded cylindrical head portion in the first phase of projectile formation. The annular pressure front acts on a second portion of the inner surface of the liner to form part of an explosively formed uniform projectile. The bell pressure front acts on a third of the inner surface of the liner to form a frustoconical portion of an explosively formed uniform projectile with a large opening angle. Explosively formed, uniform projectile, moving along its trajectory as a result of the action of detonation products of the explosive, in the intermediate stage of formation in the general range takes the shape of an irregular cone with a sharp opening angle, in order to finally reach the target shape.

The inconvenience of the remote destruction warhead for explosive formation of projectiles is its ineffective use for destroying armored vehicles, in particular tanks with thick armor at a distance that is safe for the sapper, i.e. about 30 m, and the factor causing this inconvenience is the impact of fragmentation of the periphery of the insert on the stability of the explosively formed a homogeneous projectile on its trajectory, the fragmentation of the periphery of the insert is an indispensable result of this type of fixing the insert in the housing, causing the bullet to rotate in its final phase of flight.

The aim of the invention is to eliminate the disadvantages of the known construction solutions generating explosive molded projectiles by developing a new type of mounting of the accumulating insert in the head housing.

The remote destruction warhead for explosive formation of a homogeneous projectile, according to the invention, made of a housing and a cumulative insert located near its front, a bottom embedded in the rear part of the housing, fixed by a pressure ring, of explosive material placed inside the housing between the insert and the bottom, and from the ignition means embedded in the bottom near its outer edge, situated radially, is characterized by the following technical means, their design and functional connection. In the front part of the housing, shaped internally by its two-stage cylindrical surface, a shaped mounting ring is pressed, shaped by a three-stage cylindrical outer surface and a two-stage cylindrical inner surface and a circular outer surface. Part of the two-stage cylindrical surface of the shaped mounting ring with a short radius and a radius slightly longer than the radius of the cylindrical surface of the accumulating insert creates a cavity in which this insert is pressed centrally. Part of the two-stage cylindrical surface of the shaped mounting ring with a long and slightly shorter radius than the radius of the accumulating insert, forms a low cylindrical receiving ring, which fixes the position of this accumulating insert in the shaped mounting ring, and thus in the housing. The conical part of the three-stage cylindrical-conical outer surface of the shaped mounting ring forms a truncated cone, the small base of which is directed towards the inside of the housing, and its axis coincides with the longitudinal axis of symmetry of the housing. A part of the two-stage cylindrical surface of the short-forming inner housing is formed by the low abutment collar of this housing, which fixes the position of the shaped retaining ring in its front part. The shaped retaining ring is made of metal, preferably duralumin.

The warhead in question has the advantage that the explosively formed, uniform projectile it generates has high stability on its trajectory, does not rotate and is characterized by high accuracy and high firepower of objects with armor thickness of 70 mm.

An alternative remote missile warhead for explosive formation of a single projectile, made of a housing, a cumulative insert placed inside the housing and located near its front, a bottom embedded in the rear part of the housing, fixed with a ring

A pressure plate, made of an explosive placed inside the casing between the accumulating insert and the bottom, and of ignition means embedded in the bottom near its outer edge, located radially, is characterized by the following technical means, its design and functional connection. In a conventionally positioned detent flange part of the housing, modified by increasing its height and reducing the diameters of its two-stage cylindrical inner surface, a cumulative insert is pressed in, with the apex conventionally directed towards the center of the head. The accumulating insert has a two-stage cylindrical surface the first portion of which has a radius slightly shorter than the radius of the first portion of the two-stage cylindrical surface of the inner ring flange and the second portion of which has a radius slightly shorter than the radius of the second portion of the two-stage cylindrical surface of the inner ring flange. The second part of the two-stage cylindrical surface of the accumulation insert is formed by a low engagement collar of this accumulation insert. A central outlet opening of the housing is formed by the first part of the two-stage cylindrical inner surface of the catch ring flange, and a low catch ring is formed by both parts of the two-stage cylindrical inner surface of the catch ring flange, which locates the accumulation insert in the catch ring flange, and thus in the housing. The forming of the first portion of the two-stage internal cylindrical surface of the detent ring flange is equal to that of the forming of the first portion of the two-stage cylindrical surface of the cylindrical accumulation insert, while the forming of the second portion of the two-stage cylindrical surface of the inner ring flange is equal to that of the forming of the second two-stage cylindrical surface of the cylindrical accumulation insert.

An alternative remote missile warhead for explosive formation of a single projectile has the advantage that the explosively formed uniform projectile generated by this warhead is characterized by a very high stability on its trajectory, achieved by the complete elimination of fragmentation of the cumulative insert periphery.

Second alternative remote control warhead for explosive formation of a single projectile, made of a casing, a cumulative insert placed near the forehead, a bottom embedded in the rear part of the casing, fixed by a pressure ring, with an explosive placed inside the casing between the cumulative insert and the bottom and from ignition means embedded in the bottom near its outer edge, situated radially, is characterized by the following technical means, their design and functional connection. In a conventionally located catch collar, which is a part of the housing, modified by increasing its height and shaping the internal opening, defined by a conical surface with a forming inclined at a slight acute angle with respect to the axis of symmetry of the housing and in the direction of the action of the outlet detonation products of the explosive, it is seated Press-fit cumulative insert with the apex conventionally pointing towards the center of the head. The conical outer surface of the accumulating insert has a generatrix inclined at an obtuse angle with respect to the symmetry axis of the housing, in total equal to a small acute angle increased by one hundred and eighty degrees. The inner opening of the annular latch flange of the housing is its centric outlet opening, the outer circular edge of which is adjacent to the outer edge of the circular accumulating insert.

The second alternative remote destruction warhead for explosive formation of a single projectile has the advantage that the explosively formed uniform projectile generated by this warhead is characterized by a very high stability on its trajectory, achieved by the complete elimination of fragmentation of the cumulative insert periphery.

The subject of the invention, in the examples of the embodiments, is shown in the drawing in which Fig. 1 shows the remote destruction warheads for the explosive forming of a uniform projectile, in an axial section together with its detail A, B, C broken down into its individual structural elements, in enlargement: A-part of the housing abutment collar; B-part of a retaining ring; C-part of the cumulative insert, Fig. 2-alternative remote destruction warhead for explosive formation of a single projectile, axial section, including its detail D, E, broken down into its individual structural elements, enlarged: D-conventionally positioned annular attachment flange modified housings acting as a retaining ring; E-part of the cumulative insert; Fig. 3-the second alternative remote control warhead for explosive formation of a single projectile, axial section, together with its detail F, G broken down into its individual structural elements, enlarged: F-conventionally located

The modified retaining ring flange of the housing fulfills the function of a snap ring; G - part of the cumulative insert, Fig. 4 - edge diagram of pressure distribution in the detonation products at the peripheral initiation of the explosive, a / - after 10 με, b / - after 15 μβ, c / - after 20 μβ, and Fig. 5 - the process of generating the explosive formation of a uniform projectile in the cross section along its trajectory.

The design of the remote firehead for explosive formation of a solid missile is as follows. The casing 1 has the shape of a cylinder, and in its rear part there is a circular cap 2 with a two-stage cylindrical outer surface, having a centrally located hole, while the bottom 2 closely adjoins the outer cylindrical surface of large diameter with the part of the two-stage internal surface of the cylindrical casing 1 with a long, which part forms the area which houses, in addition to the circular bottom 2, the pressure ring 4 and the explosive 5, hereinafter abbreviated MW 5. The pressure ring 4 is pressed between a part of the two-stage internal surface of the cylindrical casing 1 with a long and an outer cylindrical surface with a small diameter of a circular end 2, locating the end 2 in the housing 1. The housing 1, the circular end 2 and the pressure ring 4 are made of metal, preferably duralumin. A retaining ring 6 made of metal, preferably of duralumin, is pressed into the front part of the housing 1, internally shaped by its two-stage cylindrical surface 3, with a long and short-forming surface, a retaining ring 6 made of metal, preferably of duralumin, the low flange of the two-stage cylindrical surface 3 of the housing and forming a short one. annular, abutment 7 of this housing 1, positioning the lock ring 6 in its front part. The bevel ring is formed by a three-stage cylindrical-conical surface, an outer, circular outer surface and a two-stage cylindrical inner surface 8. The two cylindrical parts of the three-stage cylindrical-conical outer surface of the snap ring 6 have diameters that match the ring 6 to the two-stage cylindrical inner surface 3 press-fit 1 housing. The conical part 9 of the three-stage cylindrical-conical surface, the outer shape of the snap ring 6, forms a truncated cone, the small base of which is directed towards the inside of the housing 1, and its axis coincides with the longitudinal axis of symmetry of the housing 1. Part 10 of the two-stage cylindrical inner surface 8 of the ring a molded seat 6 with a short radius and a radius slightly longer than the radius of the cylindrical surface 11 of the accumulation insert 12, forms a recess in which this insert 12 is pressed centrally. On the other hand, part 13 of the two-stage cylindrical inner surface 8 of the shaped mounting ring 6 with a long and radius slightly shorter than the radius of the accumulation insert 12, forms a low cylindrical engagement ring 14 which fixes the position of this accumulating insert 12 in the shaped mounting ring 6, and thus in the housing 1. The storage insert 12 has the shape of a low-height spherical cup and is made of a metal, for example copper, ARMCO iron or tantalum. The accumulating insert 12 is located centrally, with its apex pointing towards the center of the head. In the vicinity of the outer edge of the circular bottom 2, there are radial ignition means 15, which constitute the detonators 15. As an initiation means 16 directly acting on the ignition means 15, an external decision block 16 is used, the output of which is connected in parallel with the detonators 15.

The process of generating an explosively formed uniform projectile 50 is characterized by selectively selected three phases of pressure distribution in explosive detonation products 5. In the first selective phase of pressure distribution in explosive detonation products 5, i.e. 10 μs from the moment of detonation initiation, MW 5 is distinguished: detonation; initial pressure 18 at the front 17 of the detonation wave; very high (cut for lack of space) pressure increase 19 at the front 17 of the detonation wave, caused by cumulative effects on the longitudinal axis of symmetry 20, thus on the charge axis of MW 5; front 21 of the shock wave reflected from the part of the two-stage cylindrical inner surface 3 with a long casing 1. In the second selective phase of pressure distribution in the detonation products of MW 5, i.e. 15 με from the moment of detonation of MW 5, the pressure distribution reaches the resulting apogee 23, it is very difficult to distinguish between the overlapping fronts, i.e. the detonation wave front 17, the shock wave front 21 reflected from the MW charge axis 5 and the detonation wave front 22 reflected from the part of the two-stage cylindrical inner surface 3 with a long forming casing 1. In the third phase of selective pressure distribution in detonation products of MW 5, that is 20 μs from the moment of detonation initiation of MW_5, the pressure distribution is already very even and has three distinctive fronts: quasiculist front 24; an annular front 25 and a bell front 26 with a short generatrix and a large opening angle. The quasi-spherical front 24 of pressure first acts on the top of the accumulating insert 12 and then on the inner, apical 27 of the surface of this insert 12 with a slight

It is delayed by its convexity, forming a hemispherical head portion 28 of the projectile 50 in the first stage of the formation of the projectile 50. The annular front 25 acts on the second portion 29 of the inner surface of the accumulation insert 12 to form a cylindrical portion 30 of an explosively formed, unitary projectile 50. The pressure bell front 26 acts on the third portion 31 of the inner surface of the accumulation insert 12 and on the conical portion 9 of the three-stage cylindrical-conical surface of the outer ring shaped shoulder 6 to form a frustoconical portion 32 of a large-angle, explosive-molded, unitary projectile 50. The bell front 26 of pressure acting on the third part 31 of the inner surface of the accumulation insert 12 and on the conical part 9 of the three-stage cylindrical-conical outer surface of the shaped seat ring 6, overcomes the slight resistance of the accumulation insert 12 in the form ring 6, resulting from the shape of the low, catch ring , cylindrical 14, being part of a lock ring 6. The bell front 26 of pressure acting on the third part 31 of the inner surface of the accumulating insert 12 and not having to overcome much resistance, does not fragment the periphery of this insert 12, so that an explosively formed, uniform projectile 50, moving along its trajectory as a result of the action of detonation products, MW 5 assumes the general range of an irregular cone shape in the general range, with an acute opening angle, in order to reach the target shape in the final phase. Such an explosively formed, unitary projectile 50 has a high stability on its trajectory, is non-rotating, and is characterized by high accuracy and high firepower of objects with armor made of 70 mm armor steel (0.7 caliber 12 cartridges).

The construction of the alternative remote firehead for explosive formation of a single projectile is as follows. The cylinder-shaped housing 33, made of metal, preferably of duralumin, comprises in its face part a conventionally disposed latch flange 34 forming part of the housing 33, modified by increasing its height and reducing the diameters of the two-stage cylindrical inner surface 35. Modified flange the annular detent 34 acts as a circlip 34 for the accumulation insert 36. The cylindrical inner surface 35 of the snap ring 34 of the housing 33 is two-stage, the first part 37 of this surface 35, defined by the maximum height of the snap ring 34, forming the outlet centric opening of the housing 33, while the second portion 38 of the two-stage cylindrical surface 35, with a radius slightly larger than the radius of the first portion 37 of this inner cylindrical surface 35, forms a central recess for the accumulation insert 36, and both portions 37, 38 of the two-stage cylindrical inner surface 35 the seat 34 is formed by a low retaining ring 40 which locates the accumulation insert 36 in the casing 34 and therefore in the housing 33. The accumulating insert 36 is spherical in shape with a low height and is made of metal, for example copper, iron. ARMCO, or from tantalum. The accumulating insert 36 is located centrally with its apex pointing towards the center of the head. The storage insert 36 has a two-stage cylindrical surface 41, the first portion 42 of which has a radius slightly shorter than the radius of the first portion 37 of the two-stage inner surface 35 of the mounting ring 34 of the housing 33, while the second portion 43 of the two-stage cylindrical surface 41 of the storage insert 36 has a radius slightly shorter than the radius of the second part 38 of the two-stage cylindrical inner surface 35 of the snap ring 34 and forms the low engaging flange 44 of this accumulating insert 36. The forming of the first portion 37 of the two-stage cylindrical inner surface 35 of the snap ring 34 is equal to that of the first portion 42 of the two-stage cylindrical surface 41 of the accumulating insert 36. The same applies to forming the second portion 38 of the two-stage cylindrical inner surface 35 of the snap ring 34, which is equal to the forming second portion 43 of the two-stage cylindrical surface 41 of the accumulating insert 36, so that the accumulating insert 36 is placed compatible with number of times in the snap ring 34, i.e. in the snap-on ring 34 of the press-fit housing 33.

Other head components, such as: a circular bottom 2, a part of a two-stage cylindrical surface of the inner casing 33 with a long junction, a pressure ring 4, an explosive 5, an ignition means 15, an initiating means 16, are shaped and functionally connected in the same way as in the first remote-to-blast head. forming a uniform projectile 50, with the exception of fixing the position of the cumulative insert 36 in the mounting ring 34 of the housing 33.

The generation of an explosively formed unitary projectile 50 by an alternative warhead characterized by selectively selected phases of pressure distribution in the detonation products of the MW 5, as is the case in the first warhead, is identical. Detonation wave front 17; initial pressure 18 at the front 17 of the detonation wave; very high pressure build-up on the front of the 17th wave

Detonation; front 22 of the shock wave reflected from a part of the cylindrical inner surface with a long casing 33, front 21 of the shock wave reflected from the charge axis of MW 5, the resulting apogee 23 of the pressure distribution; quasi-spherical front 24; the annular front 25 and the bell front 26 are produced in the alternative head and perform the same functions as the first head.

The explosively formed uniform projectile 50, generated by the alternative warhead, has a very high stability along its trajectory, achieved by the complete elimination of fragmentation at the periphery of the cumulative insert 36.

The construction of the second remote destruction head for explosive formation of the unitary projectile 50 is as follows. The casing 45, having the shape of a cylinder, made of metal, using duralumin, comprises in its front part a conventionally located latch collar 46, which is part of the casing 45, modified by increasing its height and shaping an internal opening defined by a conical surface 47 with a at a slight acute angle α with respect to the axis of symmetry 20 of the housing 45 and in the direction of the outlet products of detonation of the explosive 5. The accumulating insert 48 is pressed against the inner bore of the annular catch flange 46, with the apex conventionally directed towards the center of the head. The conical outer surface 47 of the accumulating insert 48 has a generatrix, inclined at an obtuse angle of 180 ° + α with respect to the symmetry axis 20 of the housing 45, in total equal to a small acute angle α increased by one hundred and eighty degrees. The internal opening of the detent ring 46 of the housing 45 is its central outlet opening, the outer spherical edge of which is adjacent to the outer edge of the circular storage insert 48. The storage insert 48 is spherical in shape with a low height and is made of metal, for example copper, of iron "ARMACO, or of tantalum."

The remaining components of the head, such as: a circular end cap 2, a part of the cylindrical inner surface of the long casing 45, a pressure ring 4, an explosive 5, an ignition means 15, an initiating means 16 are shaped and functionally connected in the same way as in the first remote blasting head. forming a uniform projectile 50, except for fixing the location of the accumulation insert 48 in the mounting ring 46 of the housing 45.

The generation of explosive formation of a unitary projectile 50 by the second alternative warhead, characterized by selectively selected phases of pressure distribution in the detonation products of the MW 5, is identical, as is the case in the first warhead. Detonation wave front 17; initial pressure 18 at the front 17 of the detonation wave; very high pressure build-up 19 at the front 17 of the detonation wave; shockwave front 22 reflected from a portion of the long internal cylindrical surface 45; front 21 of the shock wave reflected from the charge axis MW 5; the resulting apogee 23 pressure distribution; quasi-spherical front 24; ring front 25 and bell front 26 are produced in the second alternative head and perform the same functions as the first head.

The explosive formed, uniform projectile 50, generated by the second alternative warhead, is characterized by a very high stability on its trajectory, achieved by the complete elimination of fragmentation of the periphery of the cumulative insert 48.

Claims (9)

1. Remote destruction warhead for explosive formation of a uniform projectile, made of a casing, a cumulative insert placed inside the casing and located near its front, a bottom embedded in the rear part of the casing, fixed with a clamping ring, made of an explosive placed inside the casing between the cumulative insert with the bottom and from ignition means embedded in the bottom near its outer edges, located radially, characterized in that in the front part of the housing (1) formed internally by its two-stage cylindrical surface (3), a shaped retaining ring (6), shaped with a three-stage cylindrical surface (3), is pressed a cylindrical-conical outer surface and a two-stage cylindrical inner surface (8), and a circular outer surface, with a part (10) of the two-stage cylindrical inner surface (8) of the shaped snap ring (6) having a short and radius slightly longer than the radius of the cylindrical surface ( 11) of the accumulation insert (12), a cavity was created, in which this insert (12) is pressed in centrally, while the part (13) of the two-stage cylindrical inner surface (8) of the shaped mounting ring (6) with a long and slightly shorter radius from the radius of the cumulative insert (12) A low cylindrical latch ring (14) has been formed to locate this accumulating insert (12) in the shaped mounting ring (6), and thus in the housing (1). 2. Head according to claim 1, characterized in that a truncated cone is formed by the conical part (9) of the external cylindrical-conical surface of the snap ring (6), the small base of which is directed towards the inside of the housing (1) and its axis coincides with the longitudinal axis of symmetry. the housing (1). 3. Head according to claim The housing as claimed in claim 1, characterized in that a low abutment collar (7) of the housing (1) is formed by a part of the two-stage cylindrical surface (3) of the short-forming housing (1), which fixes the position of the lock ring (6) in its front part. 4. The head according to claim 6. A device as claimed in claim 1, characterized in that the retaining ring (6) is made of metal, preferably duralumin. 5. Remote destruction warhead for explosive formation of a homogeneous projectile made of a casing, a cumulative insert placed inside the casing and located near its front, a bottom embedded in the rear part of the casing, fixed with a clamping ring, made of an explosive placed inside the casing between the insert accumulation flange (34), which is part of the housing (33) and modified by increasing its height, is pressed against a cumulative insert (12), with the apex conventionally facing the center of the head. 6. The remote firehead as claimed in claim The device of claim 5, characterized in that the accumulation insert (36) has a two-stage cylindrical surface (41), the first portion (42) of which has a radius slightly shorter than the radius of the first portion (37) of the two-stage cylindrical inner surface (35) of the annular latch flange (34) and the second portion (43) of which has a radius slightly shorter than the radius of the second portion (38) of the two-stage cylindrical surface (35) of the ring collar (34), and through the second portion (43) of the two-stage cylindrical surface (41) of the accumulation insert (36) a low catch flange (44) of this accumulation insert (36) is formed, and the first part (37) of the two-stage cylindrical inner surface (35) of the annular catch flange (34) is formed by a centric outlet opening of the housing (33), while both parts ( 37, 38) of the two-stage cylindrical inner surface (35) of the annular catch flange (34), a low catch ring (40) is formed, locating the position the accumulation insert (36) in the detent ring flange (34) and thus in the housing (33). 7. The head according to claim 5 or 6, characterized in that the forming of the first portion (37) of the two-stage cylindrical surface (35) of the ring flange (34) is equal to that of the forming first portion (42) of the two-stage cylindrical surface (41) of the accumulation insert (36) and the forming of the second the portion (38) of the two-stage cylindrical inner surface (35) of the engagement ring flange (34) is equal to the forming second portion (43) of the two-stage cylindrical surface (41) of the accumulation insert (36). 8. Remote destruction warhead for explosive formation of a uniform projectile made of a casing, a cumulative insert placed inside the casing and located near its front, a bottom embedded in the rear part of the casing, fixed with a clamping ring, made of an explosive placed inside the casing between the insert accumulation at the bottom and from ignition means mounted in the bottom near its outer edge, located radially, characterized in that in a conventionally positioned annular catch flange (46), being part of the housing (45), modified by increasing its height and shaping the inner hole, defined by a conical surface (47) with a forming inclined at a slight acute angle (α) in relation to the symmetry axis (20) of the housing (45) and the direction of action of the outlet products of detonation of the explosive (5), a press-fit accumulative insert (48) is mounted, conventionally directed apex towards the center of the head, the outer conical surface (47) of the accumulating insert (48) having a generatrix inclined at an obtuse angle (180 + α) with respect to the symmetry axis (20) of the housing (45), in total equal to a small acute angle (α) one hundred and eighty degrees. 9. The head according to claim The device according to claim 8, characterized in that the inner bore of the detent ring flange (46) of the housing (45) is its centric outlet, the outer circular edge of which is adjacent to the outer edge of the circular accumulating insert (48).