RU2118790C1 - Fragmentation shell - Google Patents

Abstract

FIELD: artillery ammunition. SUBSTANCE: proposed fragmentation shell has body that houses explosive charge, nose or tail fuze of impact or proximity action. Explosive charge has axial cavity that houses elongated metal composite or monolithic body of round, polygon or shaped section. This shell displays amplified axial action which increases reliability of hitting of protected targets including armor ones. EFFECT: increased reliability of target hitting. 12 cl, 17 dwg

Description

 The invention relates to ammunition, and more specifically to fragmentation ammunition with axial amplification. Known fragmentation shells containing a steel body with a bottom, an explosive charge placed inside it and a head or bottom fuse of shock, remote or non-contact action. When such a projectile hits the target directly, the fragments fly apart in the transverse direction, i.e., they are located taking into account the intrinsic velocity of the projectile along the conical surface, which forms a sufficiently large angle with the axis of the projectile. With the instant action of the fuse, the projectile only affects the outer skin of the target and is not able to hit vital objects (assemblies) located inside the target. For medium and large-caliber field and tank shells that have a fuse with three settings, it is possible to change the depth of the projectile by setting the fuse before firing for one of three actions: instant, inertial or slow. For shells of automatic guns, this is not possible and, therefore, the axial action of the shell is not provided. The present invention seeks to remedy this drawback.

 The technical solution consists in the fact that the explosive charge is made with an internal cavity (tubular shape) in which an elongated composite or monolithic metal body is located, including a given crushing, circular or polygonal section made of steel or composite materials, for example, heavy alloys based on tungsten, uranium, or composites containing flammable metals, for example, aluminum, magnesium, zirconium, beryllium, while the projectile is equipped with a device that provides detonation of the charge from the inner bands tew.

The invention is illustrated by drawings:
FIG. 1 is a general diagram of a projectile with a fuse head position;
FIG. 2 is a general diagram of a projectile with a bottom arrangement of a fuse;
FIG. 3 - embodiments of the composite body;
FIG. 4 - section of a composite body with an axial rod;
FIG. 5 - section of a composite body without an axial rod;
FIG. 6 - design shell with a monolithic body;
FIG. 7 - embodiments of the axial body of a given crushing;
FIG. 8 - the effect of a projectile with a block of ready-to-use striking elements (GGE) or a collapsing axial body when it breaks on the target skin;
FIG. 9 - the action of the projectile with the block GGE or collapsing axial body when it breaks on the ground;
FIG. 10 - the effect of a projectile with a GGE block or a collapsing axial body in case of non-contact or remote detonation;
FIG. 11 - design configuration of the projectile;
FIG. 12 - dependence of the load factor on the relative diameter of the axial body and the relative wall thickness;
FIG. 13 - dependence of the radial velocity of the fragments on the relative diameter of the axial body and the relative wall thickness;
FIG. 14 - dependence of the specific kinetic energy on the relative diameter of the axial body and the relative wall thickness;
FIG. 15 - design configuration of the section;
FIG. 16 - dependence of the relative wall thickness on the relative diameter of the axial body with a fixed explosive charge cross-sectional area;
FIG. 17 is an experimental histogram of the distribution of fragments by mass.

 A general diagram of a projectile with a fuse head arrangement is shown in FIG. 1. The projectile contains a housing 1 with a bottom and a leading molded or welded belt, an explosive charge 2 with an axial cavity 3, in which a composite or monolithic metal body 4 of a round, polygonal or figured cross section is located, a head fuse 5 of shock, remote or non-contact action. The projectile may be provided with a shell (sleeve) 6 located between the axial body 4 and the explosive charge.

A general diagram of a projectile with a bottom arrangement of fuse 5 is shown in FIG. 2. The projectile is equipped with a screw-in bottom 7 containing transfer charges 8. The bottom can be made different from screw-in, and transfer charges can be located directly in the fuse case. Designs of a projectile with various embodiments of a composite body are shown in FIG. 1, 2, 3, 4, 5. The bodies can be made with a round, polygonal and curly section and according to their structure are divided into two groups:
- bodies with an axial monolithic or composite bearing rod 9 and a set of ready-made striking elements (GGE) 10 (Fig. 3a, b, c, d, e);
- composite bodies without a supporting rod, containing only a set of GGE (Fig. 3 e, g, s, and, k).

GGE can take the form of providing tight packing in the body (hexagonal prisms, cubes, trihedral prisms), and not providing tight packing (balls, cylinders, etc.). Dense installation is preferable, since it prevents deformation of the GGE during their explosive compression and reduces the unproductive energy expenditures of the explosive. In the diagrams of FIG. 3 b, c with peripheral laying of the GGE 11 and elongated GGE 12, the axial shaft 9 is provided with a flange 13, which reduces the axial inertial load when firing at the lower part of the GGE laying. In the circuit of FIG. 3D elongated GGE 14 are laid on the surface of the rod 9 at a small angle to the generatrix (α = 3 - 5 ^o ).

 Composite bodies of the second type are shown in FIG. 3 e, g, h, and, k. A variant of the body of FIG. 3e consists of a massive drummer 15 and a set of GGE 16 located on one axis, and the drummer can be located both in front of and behind the GGE block. In the embodiment of FIG. Figure 3g shows a rod with a composite length. In the embodiment of FIG. 3h, the body is composed of elongated GGE 14 and a block of compact GGE 16. In the embodiment of FIG. 3 and the body is made up of two blocks of GGE having different masses. In the embodiment of FIG. 3k, the body is filled with balls 17 into the shell, followed by filling with aggregate 18.

 Options for laying GGE in cross sections in structures with an axial rod 9 are shown in FIG. 4, in structures without an axial rod, in FIG. 5. In FIG. 4 a, b, c and FIG. 5a, b, c, d show tight-fitting configurations; FIG. 4g, and 5d - configurations with loose packing. The bodies can be made both with shell 6 and without it. The bonding of the GGE with each other, with the sheath and with the rod can be performed using adhesive bonding, press powder technology, hot pressing, winding with a thread, for example, fiberglass, etc. Body elements, i.e. rods and GGEs can be made of steel, including alloy steel, for example, aging maraging, and composite materials, for example, heavy alloys based on tungsten or uranium, or composites containing flammable metal powders of aluminum, magnesium, zirconium , beryllium.

 Designs of a projectile with various embodiments of a monolithic body are shown in FIG. 6 (a, c - with the main fuse b, d, e, e, - with the bottom).

 The axial body 4 has a support on the continuous bottom of the shell (Fig. 6a), on the upper section 19 of the shell of the shell (Fig. 6d), on the annular ledge 20 in the middle part of the shell of the shell (Fig. 6e), on the bottom and upper section of the shell (Fig. 6e). As examples, there are given variants of devices for fixing the rear part of the axial body from moving in the radial direction (Fig. 6a - using the ring 21, Fig. 6e - using a recess in the bottom of the projectile, which includes the rear end of the rod). In FIG. 6b shows a design of the axial body as a whole with a screw-in bottom 22, FIG. 6c - as a whole with the housing 1.

 In variants 6d, e, the axial body receives additional speed also due to the axial component of pressure on the conical surface of the rod. In the construction shown in FIG. 6d, the hull configuration is closest to the hull of the standard small-caliber shells of automatic guns (thin-walled front part and thick-walled rear part containing the leading belt). In this scheme, the rod receives additional speed due to the propellant action of explosive 23 charge. The presence of a thick-walled rear part of the housing provides a slow pressure drop in the detonation products with the release of a significant impulse. The transfer of detonation to the front of the charge is carried out directly through the body flange or by means of transfer charges 24. The projectile shown in FIG. 6b and intended for firing from a smoothbore gun, it stabilizes on the flight with a drop-down stabilizer 25 (shown in the open state). The shells depicted in FIG. 6c and FIG. 6d, equipped respectively with a tracer 26 and a bottom gas generator 27. Shells with a composite axial body can be equipped with similar devices.

 The choice of material of a monolithic body is determined by the conditions of use of the projectile. In shells designed to create a purely fragmentation effect, the axial monolithic body 4 is made of brittle material that breaks into fragments under the influence of a sliding detonation wave, for example, hardened hypereutectoid high-carbon steel with a pearlite-cement structure, for example, type 110G2S, hardened silicon spring spring steels of type 60С2, 70С3, 80С2, cast iron, heavy brittle alloys based on tungsten carbide type VK-8, VN-6, etc. To improve the crushing process, the following measures of predetermined crushing can be used: annular or helical cutting on the outer surface (Fig. 7a), hidden undercutting performed by applying grooves to the outer surface with their subsequent rolling (crushing) (Fig. 7b), applying to the outer the surface of embrittled annular, helical or longitudinal zones using, for example, local chemical thermal treatment, electron beam or laser processing (Fig. 7B). All these measures can be used in combination with an axial channel 28 of circular or polygonal cross-section (not shown) (Fig. 7d) or with an axial channel of a stepped profile (Fig. 7d). In designs with a head fuse and a bottom detonation assembly, the axial channel can be used as a transmission for the radiation pulse.

 In shells designed to operate on armored targets, the axial body 4 is made of strong plastic alloy steels, for example, packs 35X3NM, or plastic heavy alloys based on tungsten or uranium.

 All the described constructions are multi-purpose, i.e. designed for shooting on the ground for fragmentation and for shooting at targets - for shrapnel-penetrating action. In the embodiments of FIG. 6 a, c, d at the time of the shot, a body located in the axial channel, through a threaded assembly, receives a part of the inertial forces acting on the shell shell, unloading the latter. When a target is hit, a shell explodes with a lesion of it and surrounding objects by radially scattering fragments. In this case, the axial body continues to move forward, separating into the GGE or undergoing predetermined or natural fragmentation due to unloading waves, penetrating deep into the target and providing a large volume of damage in the beyond space (Fig. 8). In the case of bottom initiation of a tube explosive charge, the body receives an additional velocity relative to the body due to the action of oblique shock waves arising in the axial body when the detonation wave glides along it and due to the pressure of the detonation products at the rear end.

 When shooting on the ground with an impact fuse at low approach angles, characteristics for firing from small-caliber automatic guns, the front sheaf of the GGE or fragments of the axial body ricochet from the ground, especially in rocky and semi-rocky soils, creating a large depth of field of damage (Fig. 9). (29 - the affected area with fragments of the body, 30 - the affected area of the GPE of the axial body).

 When firing at ground and air targets using remote or non-contact fuses, the projectile hits the target with a beam of GPE or fragments of an axial body (Fig. 10). In this embodiment, the projectile is equivalent in action to a high-explosive fragmentation projectile with the front GPE block (patent N 2018779 of the Russian Federation). The issues of optimizing the mass of the GGE, the optimal range of detonation, etc., are considered in the paper “Axial Action Designs,” by V.A. Odintsov, publishing house of MSTU, 1995

 The advantages of the proposed projectile compared to the specified one is the large mass of the GGE block, the absence of a problem of the strength of the diaphragm assembly — the annular ledge of the housing, and the use of the entire length of the housing to obtain a radial field. The operation of a projectile with a monolithic axial body indestructible during an explosion proceeds similarly with the difference that when a body is compressed by a sliding detonation wave, it does not fracture due to the selected properties of the material, which can withstand tensile unloading stresses, and also the shell 6 weakening the pressure amplitude made of easily compressible material , for example, from aluminum alloy. The amplitude of the rarefaction wave also decreases due to the restraining effect on the expansion of the detonation products of the shell of the shell of the shell.

 In the future, the axial body, which performs the function of an armor-piercing projectile, penetrates the target, hitting internal units, for example, an engine, compartments with ammunition, etc. At the same time, high-temperature detonation products, which generally have incendiary components in their composition, for example, aluminum powder, penetrate the punched channel and cause ignition of the obstacle objects. When punching a sheet obstacle with a composite rod of a part of the rod due to production eccentricities and force interaction with the punctured barrier, especially when struck at an angle, diverge in different directions, providing a large amount of damage in the after-space. In this embodiment, the front part of the composite rod can be made of heavy alloy, maraging steel and other high-quality materials that provide reliable penetration of armor barriers, and the bottom parts of the rod are made of ordinary steel.

 In a variant of a fragmentation projectile, the fuse has shock-non-contact or shock-remote filling. The command is entered into the type of action, and in the second case, the temporary installation is entered, in a non-contact manner after the projectile leaves the barrel, for example, using muzzle solenoid rings, or in a contact way, for example, through an electrocapsule sleeve and a central conductive core of the sleeve.

 In a variant of a projectile with an indestructible axial body (fragmentation-proof armor-piercing action), the fuse is equipped with a switch-off device driven by one of the above methods. The fuse is turned off when firing at lightly armored targets in order to make the most complete use of the kinetic energy of the projectile to break through an armored obstacle.

где ρ_o,γ_o- соответственно плотность ВВ и металла оболочки;
δ_d= δ/d - толщина стенки оболочки в калибрах;
δ_Б= δ_Б/d - относительно диаметра блока ГПЭ (осевого тела).The optimal dimensions of the axial body-block of the GGE are found under the condition of maximum efficiency of the joint action of fragments of the shell and the GGE block. The calculated model of the projectile in the form of an equivalent cylinder is shown in FIG. 11. The total mass of the projectile (cylinder) Q is determined by the ratio
Q = (M + M _b + C) • q,
where M, M _b , C are, respectively, the mass of the body, the GGE block (axial body) of the explosive charge, and q is the coefficient taking into account the mass of “bottoms” (conventional value, including the bottom of the projectile, fuse, lead belt, etc.). With a fixed cylinder gauge d, length L, and wall thickness δ, an increase in the diameter of the block d _b will, on the one hand, lead to an increase in axial action due to an increase in the mass of the block M _b and, on the other hand, to a decrease in the radial effect of shell fragments due to a decrease in the charge mass C. The radial velocity of the fragments V _о depends on the load factor β = C / M, is determined by the ratio

where ρ _o , γ _o - respectively, the density of explosives and shell metal;
δ _d = δ / d is the wall thickness of the shell in calibers;
δ _B = δ _B / d - relative to the diameter of the GGE block (axial body).

Радиальная скорость V_o определяется по формуле Покровского-Джерни

где D - скорость детонации заряда ВВ.For a given value, the maximum relative diameter (β) = 0) is determined by the relation

The radial velocity V _o is determined by the Pokrovsky-Jerney formula

where D is the explosive charge detonation velocity.

Удельная кинетическая энергия W'=W/L;

Расчетные зависимости

7850 кг/м³, ρ_o= 1700 кг/м³, D = 8000 м/с, d = 40 мм = 0,04 м представлены на фиг. 12, 13, 14.The specific mass of the shell M '= M / L is defined as

Specific kinetic energy W '= W / L;

Estimated Dependencies

7850 kg / m ³ , ρ _o = 1700 kg / m ³ , D = 8000 m / s, d = 40 mm = 0.04 m are presented in FIG. 12, 13, 14.

кинетическая энергия по сравнению с соответствующей величиной при отсутствии тела (d= 0) снижается на 35%. Однако, это снижение при многофакторном анализе с успехом компенсируется мощным осевым действием потока ГПЭ. В таблице приводятся расчетные характеристики 40 мм снаряда по модели фиг. 11 с соотношениями фиг. 15 (L=3,5d, M=0,497 кг, C=0,116 кг, β = 0,234, V_o-1295 м/с, W_o= 417 кДж, q_д=1,2).As can be seen from the last graph, with an increase in the relative diameter of the axial body at a fixed relative thickness of the shell, a significant decrease in the kinetic energy of the radial field of the fragments occurs. For example, for the configuration shown in FIG. fifteen

kinetic energy compared with the corresponding value in the absence of the body (d = 0) is reduced by 35%. However, this decrease in multivariate analysis is successfully compensated by the powerful axial action of the GGE stream. The table shows the calculated characteristics of a 40 mm projectile according to the model of FIG. 11 with the ratios of FIG. 15 (L = 3.5d, M = 0.497 kg, C = 0.116 kg, β = 0.234, V _o -1295 m / s, W _o = 417 kJ, q _d = 1.2).

 The relative masses of the shell of the axial body and explosives (excluding bottoms) in the first case are 0.519, 0.360 and 0.121, and in the second 0.354, 0.563 and 0.083.

From the table it follows that under certain conditions, the kinetic energy of the axial flow W _b approaches the kinetic energy of the radial fragmentation field in statics. It should be borne in mind that due to the different geometry of the fields, the density of the axial field is an order of magnitude or more higher than the density of the radial field. It should also be borne in mind that a decrease in the radial velocity of fragments during the impact on unarmored ground and air targets is a factor that reduces the shear angle of the expansion of fragments and thereby contributes to the strengthening of the axial action in the annular volume.

связаны соотношением

где δ_do- относительная толщина стенки при отсутствии осевого тела.In the case when, for a given caliber, the charge cross-sectional area is fixed, which is a condition for the constant mass of the explosive charge, a condition for ensuring the constancy of a high-explosive action, and an increase in the diameter of the axial body occurs by reducing the wall thickness,

are related by

where δ _do is the relative wall thickness in the absence of an axial body.

представлен на фиг. 16.Dependency graph

shown in FIG. 16.

Числа осколков с массой более 0,25, 0,5 и 1,0 г составили соответственно 585, 437 и 337. Гистограмма распределения осколков по массе представлена на фиг. 17.5The sufficient crushing effect of the tube charge with an axial body was confirmed by experiment on a standard fragmentation model N 12 (patent N 2025646 of the Russian Federation) with a body made of steel C - 60 (outer diameter 60 mm, inner diameter 40 mm) containing an axial body (steel rod) with a diameter 25 mm

The numbers of fragments with a mass of more than 0.25, 0.5, and 1.0 g were 585, 437, and 337, respectively. A histogram of the distribution of fragments by mass is shown in FIG. 17.5

Claims (13)

 1. A fragmentation shell containing a shell, an explosive charge placed inside the shell, a head or bottom fuse of shock, or remote, or non-contact action, characterized in that the explosive charge is made with an axial cavity in which an elongated metal composite or monolithic round body is placed polygonal or curly section.  2. The projectile according to claim 1, characterized in that the metal body is placed with support on the bottom of the projectile.  3. The shell according to claim 1 or 2, characterized in that between the metal body and the explosive charge placed a pad of compressible material.  4. The projectile according to claim 1, characterized in that the elements of the composite body are made in a shape that ensures their tight packing in the axial cavity of the charge.  5. The projectile according to claim 1 or 4, characterized in that the elements of the composite body are made of steel, or composite materials based on tungsten or uranium, or alloys containing flammable metals.  6. The projectile according to any one of paragraphs.1,4 and 5, characterized in that the elements of the composite body are made in the form of rods.  7. A projectile according to any one of claims 1, 5 and 6, characterized in that the composite body contains an axial bearing rod and a set of ready-made striking elements located around it.  8. A shell according to any one of claims 1 to 3, characterized in that the monolithic metal body is made of brittle metal material.  9. The projectile according to any one of claims 1 to 3, characterized in that the monolithic metal body is made of plastic metal material.  10. The projectile according to any one of claims 1, 8 and 9, characterized in that the monolithic metal body is equipped with a predetermined crushing device in the form of an annular or helical undercut on its outer surface or embrittled zones.  11. The projectile according to any one of claims 1, 8 to 10, characterized in that the monolithic metal body is made with an axial channel of circular or polygonal section or step profile.  12. The projectile according to claim 1, characterized in that the fuse is made with shock-non-contact or shock-remote action.  13. The projectile according to claim 12, characterized in that the fuse is equipped with a shutdown device.

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