RU2520191C1 - Light shell of close-range weapon (mining, infantry) - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: light shell of mobile weapon includes a shell body with a nose fuse and an explosive charge. Shell is made of two attached parts - rear calibre cylindrical weaponhead part and front part. Rear calibre weaponhead part consists of a fragmentation housing filled with an explosive and a detonation assembly. The front part includes a hollow fairing, in the front part of which the main contact assembly or a fuse connected through a quick-action connection to the detonation assembly of the rear part is located.

EFFECT: improving fighting efficiency of light shells for mobile weapons.

20 cl, 11 dwg

Description

The invention relates to ammunition, and more particularly to shells of light artillery guns of internal, border, mountain, airborne troops, marines, as well as troops operating in the Arctic. The shells of these guns should have a small mass, providing a small recoil of the gun when fired. Light shells are known. The 152 mm M657 high-explosive fragmentation shell for the M21 short-barreled tank gun of the Sheridan and M60A2 tanks (USA) had a shell weight of 19 kg, while the shells of regular 152 mm field guns had a mass of 43 ... 45 kg. This shell is adopted as a prototype of the invention.

The shell, built according to the classical scheme, contains a shell with a charge of explosive (BB) and a head impact fuse. The reduction in mass was achieved due to a significant reduction in the length of the projectile (the ratio of projectile length to caliber is 2.86, while for regular shells it ranges from 4.5 ... 5.5).

It is known that for shells of field tools with large angles of incidence of the projectile on the ground, shortening the projectile reduces the effectiveness of its fragmentation effect. This is due to the fact that the shell manages to penetrate into the ground for a significant part of the body length before undermining, which leads to the interception of a large part of the fragments by the soil.

The present invention seeks to remedy this drawback. The technical solution consists in the fact that the projectile is made up of two connected parts:

- rear caliber cylindrical warhead, consisting of a steel fragmentation shell filled with a charge of explosive (BB) containing a detonation unit;

- the front hollow part containing a cowl made of a light metal alloy or plastic, including the use of nanomaterials containing a head contact assembly (or fuse) connected by a quick coupling (electrical or detonation) to the detonation assembly of the rear part.

This solution allows to reduce the mass of the projectile by two or more times compared to the mass of the standard projectile, to provide the desired distance between the center of mass and the center of pressure of the projectile, necessary for its gyroscopic stability in flight, and to provide detonation of the warhead of the projectile at a certain distance from the earth’s surface, providing minimum interception of fragments by soil.

Along with this, the cylindrical shape of the warhead allows you to implement designs with various types of action.

Illustrations: figure 1 - fragmentation shell; figure 2 - fragmentation projectile, creating an increased meridional angle of flight of fragments; figure 3 - fragmentation-beam projectile; figure 4 - cumulative projectile; 5 is a concrete-piercing projectile using an impact core; 6 is an adjustable projectile.

The projectile shown in figure 1, consists of two parts: the rear gauge cylindrical part (warhead) 1 and the front hollow part 2. Part 1 includes a steel fragmentation case 3, filled with a charge 4 of explosive, with detonation unit 5. Leading the belt 6 is located on the outer surface of the bottom of the housing. Part 2 includes a head hollow cone 7 of a conical or animated shape made of light metal alloy or plastic, including using nanomaterials, a blasting head assembly 8 and a signal transmission channel 9. The design of block 8 and channel 9 depends on the blasting method adopted . With the electric blasting method, block 8 contains a circuit breaker or a piezoelectric generator, channel 9 is an electrical conductor, the detonator capsule and the safety mechanism are located in the detonation unit 5.

With the mechanical method of blasting, block 8 is made in the form of a conventional shock (contact) fuse, channel 9 represents an elongated explosive charge with a possible execution in the form of a detonating cord.

Projectile proportions and material requirements were determined for a new projectile fired from a Tver light gun [1] in the range of calibers 100 ... 120 mm, firing range 5 ... 6 km, muzzle velocity 250 ... 300 m / s, relative projectile mass C _q less than 6 kg / dm ³ , the filling factor of the projectile (the ratio of the mass of the explosive charge to the mass of the projectile) 0.30 ... 0.35. At the same time, the requirement was imposed that the combat effectiveness of the new projectile for the “infantry in body armor” target should not be lower than that of a full-fledged standard projectile of the same caliber.

The ratio of the height of the warhead to the caliber of the projectile is in the range of 1.0 ... 1.5, and the ratio of the wall thickness to the caliber is in the range of 0.05 ... 0.08. The body of the warhead is made of steel, preferably high-fragmentation, for example 60С2 [2], 80Г2С [3], 80С2 [4]. The ratio of the mass of the explosive charge to the mass of the projectile is in the range of 0.30 ... 0.35. The detonation velocity of the explosive charge of the warhead is at least 8800 m / s.

The fairing is made of light metal alloy or plastic, including the use of nanomaterials. The ratio of the height of the fairing to the caliber of the projectile is in the range of 1.5 ... 2.0, and the ratio of the wall thickness to the caliber is in the range of 0.02 ... 0.03.

Figure 2 presents a fragmentation projectile that creates an increased meridional angle of expansion of the fragments, which is achieved by the execution of the warhead with a convex curvilinear generatrix.

Figure 3 shows the design of the projectile according to the scheme of a fragmentation-beam projectile [5]. At the front end of the explosive charge is a block of ready-made striking elements (GGE) 10 made of steel or heavy alloys based on tungsten. The detonation unit 5 is shifted to the bottom of the projectile, which ensures the detonation wave falls on the block with an increase in its throwing speed. This projectile uses a head trajectory fuse, which provides for the detonation of the projectile on the trajectory at an anticipated point in front of the target. As a trajectory fuse, fuses of time, number of revolutions, non-contact or command type can be used.

Figure 4 presents the performance of the projectile cumulative type. A cumulative funnel 11 is placed along the axis of the explosive charge 11. To reduce the harmful effects of projectile rotation on the cumulative jet, the funnel is made in the form of a body having an N-order rotation symmetry (N = 12 ... 30) [6].

In a cumulative projectile, it is advisable to use a blasting scheme that does not contain a transmission channel, the presence of which can worsen the conditions for the formation of a cumulative jet. A charge with a cumulative funnel 12 is connected to the main fuse, and detonation unit 5 contains a charge 13 of a sensitive explosive capable of detonating when a cumulative jet gets into it from the funnel 12.

Figure 5 shows the design of a concrete-piercing projectile using an impact core. At the front end of the explosive charge there is a concave segmented lining 14 (ballistic disk), which forms a high-speed compact impactor (impact core) during the explosion of the charge.

Figure 6 presents the performance of the projectile corrected type. The projectile is used with a semi-active guidance system with target illumination by a laser beam from an external source. In this design, the correction of the trajectory is carried out due to the shooting of ballast weights. The receiver 15 of the reflected from the target laser radiation is located in front of the fuse. Block 16 of ballast weights contains radially located barrel chambers 17 with ballast weights 18 placed therein, powder propellant charges 19 and igniters 20. The block is located in the plane of the center of mass of the projectile. Management of the shooting of goods is carried out using the control compartment 21.

Figure 7 shows the design of a projectile forming a group of impact cores. At the front end of the explosive charge there is a round plate 22 with several spherical recesses (menisci) extruded thereon 23. The plate can be made of steel or heavy alloy. View of the plate from the side of the fuse is shown in Fig. 8. To increase the area of the menisci and, as a consequence, increase the mass of the formed impact nuclei, mutual partial intersection of the circles of the menisci is allowed (Fig. 9), while the ratio of the distance l between the centers of the menisci to the diameter of the meniscus should be at least 0.8.

Figure 10 shows the execution of the plate in the form of a cone, the vertex facing the head of the projectile, while the angle γ between the generatrix of the cone and the plane normal to the axis of the projectile is within 2 ... 10 °. To increase the speed of throwing shock nuclei, an option is provided for the explosive charge to be composite, with the back of the charge 24 adjacent to the detonator made of an economical typical explosive (for example, A-1X-2), and the front of the charge 25 adjacent to a plate made of explosive with a detonation velocity of more than 8800 m / s (for example, phlegmatized HMX, CL-20).

A variant is provided in which the conjugation of both parts of the charge is made on the surface 26, the shape of which ensures the conversion of a spherical detonation wave diverging from the detonator into a conical parallel to the conical surface of the plate.

There are also other types of execution of the striking elements, throwing from the front end of the warhead, including in the form of a set of tightly laid rods 27 square section (11). A number of possible designs of the damaging elements were proposed in [7].

The effect of shells.

The shells of figure 1, 2, 6, depending on the conditions of detonation (ground, air) are equipped with either an economical impact, or more expensive impact trajectory fuse. In the latter case, the fuse is set to the type of action before the shot.

The projectile of FIG. 3 is equipped with a trajectory fuse, the projectiles of FIGS. 4, 5 — shock fuses.

When firing at an impact, the blasting system provides undermining of the warhead at a certain distance from the surface of the obstacle. Due to this, for a fragmentation projectile, minimal interception of fragments by the soil surface is ensured, and for cumulative and concrete-piercing shells, accordingly, the possibility of developing a cumulative jet to an optimal length and complete formation of the impact nucleus. The shock core is capable of forming a large-sized hole in the wall with a powerful backward action.

When firing a fragmentation-beam projectile (Fig. 3), a trajectory detonation is carried out with the formation of two fragmentation fields - a circular field of fragmentation fragments of the warhead body and the axial field of the finished striking elements. Shooting at short ranges along a lay trajectory ensures the realization of deep lesion fields; shooting along a mounted trajectory ensures destruction of targets in trenches, embankments and on reverse slopes.

When firing a corrected projectile (Fig.6) from light guns providing a low firing range, laser illumination of the target is carried out directly from the gun, which eliminates the technically difficult operation of delivering a "highlighter" to the target area and ensuring continuous communication with it.

Aiming the projectile during the flight at the illuminated target is carried out by shooting ballast weights.

Technical result: the invention allows to form a set of light shells for mobile (infantry, mountain) guns, which allows to solve a variety of combat missions.

Literature

1. RU 2213315.

2. RU 2079099.

3. RU 2153024.

4. RU 2368691.

5. Odinotsv V.A. Shrapnel-beam shells. Defense Technology, 2006, No. 2.

6. RU 2406062.

7. RU 2194240.

Claims (20)

1. A light projectile of a mobile gun containing a shell of a projectile with a head fuse and an explosive charge, characterized in that the projectile is made of two connected parts: a rear caliber cylindrical warhead consisting of a fragmentation shell filled with explosive and containing a detonation assembly, and the front part, containing a hollow cowl, in the front part of which there is a head contact unit or fuse connected by a quick coupling with the detonation unit of the rear part. 2. The projectile according to claim 1, characterized in that the ratio of the height of the warhead to the caliber of the projectile is in the range of 1.0 ... 1.5, and the ratio of the wall thickness of the shell to the caliber is in the range of 0.05 ... 0.08. 3. The projectile according to claim 1, characterized in that the warhead housing is made of steel, preferably high-fragmentation, for example 60C2, 80G2S, 80C2. 4. The projectile according to claim 1, characterized in that the ratio of the mass of the explosive charge to the mass of the projectile is in the range of 0.30 ... 0.35. 5. The projectile according to claim 1, characterized in that the detonation velocity of the explosive charge of the warhead should be at least 8800 m / s. 6. The projectile according to claim 1, characterized in that the fairing is made of light metal alloy or plastic, including using nanomaterials. 7. The projectile according to claim 1 or 2, characterized in that the ratio of the height of the fairing to the caliber of the projectile is in the range of 1.5 ... 2.0, and the ratio of the wall thickness to the caliber is in the range of 0.02 ... 0.03. 8. The projectile according to claim 1, characterized in that the warhead housing is made with a convex curvilinear generatrix. 9. The projectile according to claim 1, characterized in that at the front end of the charge of the warhead there is a block of ready-made striking elements made of steel or heavy alloys based on tungsten, the detonation assembly is shifted to the bottom of the projectile, the head fuse is made in the form of a trajectory fuse. 10. The projectile according to claim 9, characterized in that the trajectory fuse is made either temporary, or number of revolutions, or non-contact, or command type. 11. The projectile according to claim 1, characterized in that a cumulative funnel in the form of a body having an N-order rotation symmetry (N = 12 ... 30) is placed along the axis of the explosive charge, a charge with a cumulative funnel is connected to the head fuse, and a detonation the node contains a charge of a sensitive explosive capable of detonating when a cumulative jet enters it. 12. The projectile according to claim 1, characterized in that at the front end of the explosive charge there is a concave segmented lining, which forms a high-speed compact impactor — impact core during explosion of the charge. 13. The projectile according to claim 1, characterized in that in front of the fuse there is a receiver of laser radiation reflected from the target, between the front and rear parts in the plane of the center of mass of the projectile there is a ballast block containing radially located barrel chambers with ballast weights placed in them, powder propelling charges and igniters, and a control compartment is attached to the unit. 14. The projectile according to claim 1, characterized in that the lead belt is located on the outer surface of the bottom of the shell of the warhead. 15. The projectile according to claim 1, characterized in that at the front end of the explosive charge there is a round plate with several spherical depressions extruded on it, made of steel or heavy alloy. 16. The projectile according to claim 1 or 15, characterized in that the plate is made with a partial mutual intersection of the circumference of the menisci, while the ratio of the distance between the centers of the menisci to the diameter of the meniscus is at least 0.8. 17. The projectile according to claim 1, characterized in that the plate is made in the form of a cone, the vertex facing the head of the projectile, while the angle between the generatrix of the cone and the plane normal to the axis of the projectile is within 2 ... 10 degrees.      18. The projectile according to claim 17, characterized in that the explosive charge of the warhead is made integral, while the back of the charge adjacent to the detonator is made of an economical typical explosive, for example A-1X-2, the front of the charge adjacent to the plate is made of explosive with a detonation speed of more than 8800 m / s, for example phlegmatized HMX CL-20. 19. The projectile according to claim 1 or 18, characterized in that the conjugation of both parts of the charge is made on a surface whose shape provides the conversion of a spherical detonation wave diverging from the detonator into a conical parallel to the conical surface of the plate. 20. The projectile according to claim 1, characterized in that at the front end of the explosive charge there is a set of tightly packed square rods.

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