RU2206862C1 - Concrete-piercing ammunition - Google Patents

Abstract

FIELD: destruction of permanent defenses made of reinforced concrete, strong stone and brick buildings. SUBSTANCE: a blasting means for formation of a hole provided with a fuse is located in the front part of the ammunition. A piercing bursting charge, explosive charge and a base fuse provided with a retarder are positioned in the rear part. The piercing bursting charge is made as a subcaliber or caliber one. The blasting means for formation of a hole is made as a caliber one and provided with a shaped charge or some other blasting means of axial action. The ammunition is provided with a head cap, bourrelet and a driving band. The bourrelet is positioned mainly on the blasting means, and the driving band - on the caliber piercing bursting charge. The shell with a subcaliber piercing bursting charge may have a detachable sabot fastened to the charge by locks. The sabot may be provided with a high-pressure chamber, calibrated hole and a driving band. The blasting means may be made as a shaped-charge warhead containing a shaped-charge funnel located in the axis of the warhead, and an explosive charge. The blasting means may be made as an explosive charge with a facing for formation of the impact core. EFFECT: considerably improved piercing effect. 18 cl, 10 dwg

Description

 The invention relates to ammunition, and more specifically to concrete-piercing ammunition.

 Concrete-piercing shells are known for destroying long-term structures made of reinforced concrete, strong stone and brick buildings and consisting of a hull, explosive charge, screw bottom and fuse (Soviet Military Encyclopedia. M: 1976, vol. I, p. 465). Concrete punching work is carried out mainly due to the kinetic energy of the projectile, therefore, sufficiently high projectile speeds are required, which are achievable only in guns with a large mass (7-8 tons with a caliber of 152 mm). The experience of regional wars revealed the urgent task of developing a light (assault) gun (weighing up to 1 ton in a caliber of 152 mm) with a small initial velocity (250-300 m / s) and a small firing range (5-7 km) (see, for example , A.I. Nikolaev, V. A. Odintsov. "For regional conflicts, assault weapons are needed." "Armament. Politics. Conversion", 2000, 5). Moreover, in regional conflicts, the task of defeating solid obstacles (brick, stone, concrete, mud walls, shelters in caves, etc.) remains very important. This implies the need to develop a low-speed concrete-piercing projectile with high efficiency.

 In the West German small-caliber concrete-piercing bomb STABO (see I. Karenin. "Airborne weapons for attacking airfields." Zarub. Military Review, 1984, 12, p. 55) is the closest to the invention by the combination of essential features, which is a low-speed munition, high efficiency is achieved by placing a cumulative charge in the front of the munition, which is a means of forming a hole in the concrete, and in the back of a penetrating explosive shell equipped with a bottom fuse with a delay element . In this case, the cumulative charge (precharge) is made of caliber, and the penetrating projectile (penetrator) is made of a sub-caliber placed inside the thin-walled caliber body.

 This design is not applicable in an artillery shell of a rifled gun, which has a leading belt as an obligatory element, since the compression of the latter when cutting into the rifled guns will lead to unacceptable deformation of the thin-walled body. An increase in the thickness of the casing is unacceptable due to an increase in its mass, which is essentially ballast, i.e. not directly involved in breaking through the barrier.

 A significant design flaw is the lack of a head cover. The absence of a head cap, on the one hand, increases air resistance, and on the other hand, does not allow the development of a cumulative jet to the desired length. With certain combinations of the characteristics of the projectile and the obstacle, the cumulative effect of the jet may not ensure the formation of holes in the concrete with a diameter sufficient for free passage of the penetrating projectile.

 Limiting the performance of the precharge only in the form of a cumulative charge, which creates a relatively narrow hole in concrete, narrows the range of application of concrete-piercing shells of divided action. There are a number of situations (for example, if it is necessary to form holes in the wall with large transverse dimensions) in which it is more appropriate to use an explosive precharge acting on a different principle, for example, with the formation of an impact core, deformation of a plastic explosive before undermining a charge, etc.

 The use of a sub-caliber penetrator leads to a decrease in the mass of the explosive charge carried over the obstacle, and, consequently, to a decrease in the backward action, i.e. is a design flaw.

 As far as one can judge from the description, no special measures have been taken in the design to enhance the beyond-fragmentation, compression, and incendiary effect of the explosion of the charge of the intruder.

 The allowable minimum distance between the bottom of the precharge and the tip of the intruder, as well as the material of the bottom of the precharge and its thickness, are not specified. When the bottom is made of steel, a blow to it on the top of the penetrator, especially in the presence of blunting of the head part of the penetrator, can lead both to inhibition of the penetrator and to the initiation of detonation in the explosive charge of the intruder.

 The present invention addresses these drawbacks. The technical solution consists in the fact that a detachable caliber tray is introduced, the projectile is equipped with a head cap, a centering bulge and a lead belt, the centering bulge being placed mainly on the precharge, and the lead belt on the caliber penetrator or pallet, the precharge is made with the possibility of using cumulative charge, and charge with a "shock nucleus", deformable charge of plastic explosive, charge with a ring cumulative groove, etc., when executed penetrate If measures are taken that reinforce the refractory fragmentation and compression action (predetermined crushing, central initiation, high-fragmentation steel, explosive compositions of thermocompression action), the penetrator fuse deceleration element is made with adjustable deceleration time, the distance between the precharge bottom and the penetrator tip is performed in accordance with the calculation data for the proposed formula.

 FIG. 1 a, b is a general diagram of a concrete-piercing munition, FIG. 2 is a construction of a concrete-piercing artillery shell with a cumulative precharge and a subcaliber penetrator, FIG. 3 is an artillery shell with a pre-charged “impact core”, a piercing penetrator and a pallet, FIG. 4 is a concrete-piercing artillery shell with a flattening type precharge and caliber penetrator, FIG. 5 - a concrete-piercing projectile with a precharge based on an annular gutter-shaped cumulative recess, a caliber penetrator and a jet accelerator, FIG. 6 - adjustable concrete-piercing projectile with a multi-cumulative precharge and caliber penetrator, Fig. 7,8 - device pre-charge multi-cumulative type, Fig. 9 - action of the projectile with a pre-charge "impact core", Fig. 10 - the action of the projectile with a flattening type charge.

 The proposed ammunition (Fig. 1) consists of two main parts - a penetrating explosive projectile 1 subcaliber (a) or caliber (b) type and explosive means 2 forming holes in the barrier (precharge). The formation of the hole can be realized using the cumulative effect, an explosive shock, a flattening charge of a plastic explosive or other schemes. The performance of the ammunition is shown in FIGS. 2-6 (FIG. 2,3 is a subcaliber type intruder, FIGS. 4-6 is a caliber type intruder).

где d_пз - диаметр предзаряда, м; d_пр - диаметр проникателя, м; h -толщина свода стального корпуса проникателя по оси, м; h_д - толщина слоя демпфера 43; m' - удельная масса дна предзаряда, кг/м².Ammunition according to the scheme of figure 2 includes a housing 3 with a leading belt 4 pressed into it, a diaphragm 5 and a centering thickening 6. In the bottom of the housing, a piercing piercing explosive projectile (penetrator) 1 with housing 7, explosive charge 8, screw bottom 9 and a bottom fuse 10. In the front thin-walled part of the housing 3, a charge of BB 11 is placed with a detonator 12 and a cumulative funnel 13. A head cap 14 with a head impact fuse 15 is attached to the front housing. The bottom of the precharge is made primarily of low-density material, for example, aluminum mini alloys or plastic. The bottom can be made convex towards the bottom of the projectile to realize the spatial expansion of the fragments and reduce the momentum at the front end of the intruder. The distance Δ between the bottom of the precharge and the tip of the penetrator should be greater than Δ _cr , where Δ _cr is determined by the formula

where d _pz is the diameter of the precharge, m; d _CR - the diameter of the penetrator, m; h is the thickness of the arch of the steel body of the intruder along the axis, m; h _d - the thickness of the layer of the damper 43; m 'is the specific gravity of the bottom of the charge, kg / m ² .

 Ammunition according to the scheme of FIG. 3, also made with a sub-caliber penetrator 1, characterized in that the explosive charge 16 with a lining 17 is used as a precharge to form a shock core (explosive shock), and the bottom of the penetrator 1 is connected to a detachable tray 18 provided with a leading girdle 19, a high chamber pressure 20, connected by a channel 21 to the atmosphere and cut-off stoppers 22, fastening the pallet with the body of the penetrator. Another difference is that in the rear cavity of the precharge is an incendiary composition 23.

 The ammunition according to the scheme of figure 4 includes a caliber penetrator consisting of a caliber housing 24 with a drive belt 4 pressed into it, a screw bottom 25 with a bottom fuse 26 and an explosive charge 27. The penetrator is fastened with a threaded joint 28 to a precharge housing made of low carbon ductile steel. A plastic explosive charge (29) is placed inside the case (for example, the composition of hexogen - zinc stearate 80/20), and a damper (30) is placed in the front part of the case, made in the form of a hemisphere, made, for example, of plastic. The charge of the plastic explosive is equipped with a bottom fuse 31 with an element of auto-controlled deceleration. A damper 43 is mounted in front of the explosive charge of the intruder.

 Figure 5 shows a projectile with a caliber penetrator, a precharge made in the form of a cumulative warhead 32 containing an annular cumulative groove 33, a charge BB 34 and an explosive wiring system 35. In the bottom part, the caliber penetrator is equipped with a jet engine 36 with a device 37 for turning on the engine moment of impact on the obstacle.

 The corrected concrete projectile with a caliber penetrator, shown in Fig.6, is equipped with a precharge made in the form of a cumulative warhead containing an axial cumulative funnel 38, a cumulative annular groove 33, a charge BB 34 and an explosive wiring system 35. The charge of the penetrator BB is equipped with a central initiation detonator 39. Correction of the flight of the projectile is carried out using the correction unit 40 of the jet or ballast type located in the middle of the projectile and electrically connected to the radiation receiver 41.

 In order to enhance the fragmentation-shielding effect, the penetrator body can be made with predetermined crushing, using high-fragmentation steels, for example, 60С2 silicon steels (patents 2079099, 2095740 RF), 80С2 or 80Г2С eutectoid steel (RF patent 2153024), and using central charge initiation Explosive explosive, providing an increase in the meridional angle of flight of fragments beyond the barrier.

 Strengthening the thermocompression effect of an explosion behind an obstacle (the effect of high temperature and pressure) can be achieved by equipping the penetrator with an explosive composition (for example, RDX, HMX) - metal powder (for example, aluminum, magnesium, beryllium) with a powder content in the range of 25-30 % It is known that the use in explosive shells of compositions with a high content of aluminum powder leads to a decrease in the crushing (blasting) effect of explosives (see, for example, Odintsov V.A., Shkalyabin I.O. "Crushing effect of explosives in standardized cylinders." Combustion physics). and explosion, 1994, 3) and ultimately to a deterioration of the fragmentation effect. The use together with these compositions of high-fragmentation steels 60С2, 80С2, 80Г2С will make it possible to compensate for the decrease in fragmentation action and keep it at the level characteristic of the standard combination of steel S-60 - composition A-IX-2.

 The lead belt is located on the shell of the projectile (Fig. 2), on a pallet (Fig. 3) or on the body of the penetrator (Figs. 4,5,6) in the region of the bottom or diaphragm, which ensures that there is no deflection of the material under the belt when cutting into the guns and reliable transmission of torque to the projectile.

 Detachable tray (figure 3) provides a more rational distribution of the load on the body of the intruder. The separation of the pallet is as follows. When the projectile moves along the bore, the powder gases pass through the channel 21 into the high-pressure chamber 20, however, the separation of the tray from the front of the projectile does not pass, because the latter is pressed against the pallet by linear acceleration. When this force ceases to act after the projectile leaves the bore, the powder gases located in the high-pressure chamber push the front part out of the pallet with the cut-off stopper 22.

 Incendiary composition 23, located in the rear cavity of the precharge, after impact penetrates into the hole pierced by the precharge, and provides ignition of objects that are behind the obstacle (fuel tanks, ammunition, etc.).

 The scheme of action of the projectile with a pre-charge type "impact core" (Fig.3) is presented in Fig.9. When a projectile hits a brick or concrete obstacle, a head detonator fires, causing the precharge to detonate and form an “impact nucleus” 44. The “impact nucleus” penetrates the obstacle to form a well into which a penetrating explosive projectile penetrates, in this case a caliber type. In the absence of through penetration of the barrier by the “impact core", the remaining part of the barrier is broken by the intruder itself. After it leaves the barrier through the moderator, the charge of the intruder is undermined and the obstacles are hit by fragments, detonation products, and an air shock wave.

 The action diagram of a projectile with a flattening type charge (Fig. 4) is shown in Fig. 10. When hitting an obstacle, a thin precharge shell made of plastic steel, together with a plastic explosive charge, deforms and spreads over the obstacle surface, increasing the contact area and thereby increasing the active mass of the charge (Explosion Physics, edited by KP Stanyukovich, Science, 1975, p. 313). Damper 30 prevents the initiation of an explosive explosion upon impact. The fuse 31 with an element of auto-controlled deceleration, depending on the conditions of the impact (speed and angle of approach of the projectile, material and thickness of the barrier, etc.) provides undermining of the charge of the penetrator at the moment corresponding to the maximum efficiency. In this case, a large diameter hole is formed in the barrier.

 The formation of holes with large transverse dimensions is also provided by a precharge with an annular cumulative groove (Figs. 5-8). At the same time, a cylindrical block is cut down in concrete, which is then pushed out over the obstacle by the front end of the intruder. To facilitate ejection, the block can be further destroyed by axial cumulative charge 38 (Fig.6). The explosive wiring system 35, made in the form of a plane detonation wave generator, multipoint triggering, channel wiring, etc., provides a symmetrical loading of the annular groove. Precharges of this type are especially effective when operating on reinforced concrete (reinforced concrete).

 To increase the penetration ability of penetrators, all types of shells can be equipped with jet solid-fuel fast burning engines located in the bottom of the penetrators. Engines are turned on when the projectile hits concrete with the help of a switch 37.

 For long-range shooting at small-sized concrete targets (for example, caps of long-term firing points), all types of shells can be equipped with trajectory correction units 40 of jet or ballast type, located in the middle part of the projectile near the center of mass and electrically connected to the radiation receiver 41.

Claims (18)

 1. Concrete ammunition containing in front of an explosive means of forming holes in the barrier, equipped with a fuse, and in the rear of a penetrating explosive projectile having a body, explosive charge and a bottom fuse equipped with a delay element, characterized in that the penetrating explosive shell is made or subcaliber, or caliber, explosive means of forming holes made caliber and equipped with a cumulative charge or other explosive means of axial action, the munition is equipped with a head a cap, a centering thickening and a leading girdle, the centering thickening being located mainly on the explosive means of hole formation, and the leading girdle - on a caliber penetrating explosive shell.  2. The ammunition according to claim 1, characterized in that the projectile with a sub-caliber penetrating explosive projectile contains a detachable pallet fastened to the projectile by stoppers.  3. The ammunition according to claim 2, characterized in that the pallet is equipped with a high-pressure chamber, a calibrated hole and a driving belt.  4. The ammunition according to claim 1, characterized in that the explosive hole formation means is made in the form of a cumulative warhead containing a cumulative funnel located along the axis of the warhead and an explosive charge.  5. The ammunition according to claim 1, characterized in that the explosive hole formation means is made in the form of an explosive charge with a lining to form an impact core.  6. The ammunition according to claim 1, characterized in that the explosive formation means is made in the form of a deformable charge of a plastic explosive.  7. The ammunition according to claim 1, characterized in that the explosive hole formation means is made in the form of a cumulative warhead containing an annular cumulative groove and an explosive charge.  8. Ammunition according to claim 4, characterized in that the cumulative warhead contains an annular cumulative groove.  9. Ammunition according to any one of paragraphs.4-8, characterized in that it is equipped with a bottom jet engine with a switch-on device at the time of impact against the obstacle.  10. The ammunition according to claim 1, characterized in that the body of the penetrating explosive shell is made with the possibility of a given crushing.  11. The ammunition according to claim 1, characterized in that the explosive charge of the penetrating explosive projectile is equipped with a detonator located in the central part of the projectile along the length.  12. The ammunition according to claim 1, characterized in that the body of the penetrating explosive shell is made of high-fragmentation steel 60С2, or 80С2, or 80Г2С.  13. The ammunition according to claim 1, characterized in that the explosive charge penetrating explosive burst represents the composition of the thermocompression action with the content of aluminum powder in the range of 25-30%.  14. Ammunition according to claims 12 and 13, characterized in that the body of the penetrating explosive shell is made of high-fragmentation steels 60С2, 80С2, 80Г2С, and the equipment is made with the composition of the thermocompression action according to item 13.  15. The ammunition according to claim 6, characterized in that the explosive hole forming means comprises a shell of a plastic low-carbon steel body and equipment from a plastic explosive.  16. The ammunition according to claim 1, characterized in that the deceleration element of the fuse of the penetrating explosive shell is made with an adjustable deceleration time. 17. The ammunition according to claim 1, characterized in that the distance between the bottom of the explosive means of forming holes and the top of the penetrating explosive projectile is made large Δ _cr where Δ _cr , is determined by the formula

where d _pz is the diameter of the precharge, m;
d _CR - the diameter of the penetrator, m;
h is the thickness of the arch of the steel body of the intruder along the axis, m;
h _d - the thickness of the layer of the damper;
m 'is the specific gravity of the bottom of the charge, kg / m ² .  18. The ammunition according to claim 1, characterized in that it contains a radiation receiver in the head part, and in the middle part of the projectile a trajectory correction unit of the jet or ballast type, electrically connected to the radiation receiver.

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