RU192661U1 - High-explosive armor-piercing projectile - Google Patents

Abstract

The proposed device relates to the field of artillery ammunition, namely to high-explosive-explosive ordnance, and can be used in military operations in urban conditions. , leading device, a screwed bottom with a bottom fuse, characterized in that the housing consists of a separate cylinder and ballistic tip, the explosive charge is of primary explosive and the lens of the explosive with a high rate detonatsii.Zadachey (technical result) of the proposed utility model is to increase the area of spall from the rear barrier or square through-penetration in the case of small obstruction width.

Description

The alleged device relates to the field of artillery ammunition, namely to high-explosive armor-piercing ordnance, and can be used in combat in urban environments.

Famous high-explosive armor-piercing projectile (105 mm Round, fixed with HESH-T Shell M67 // Marstar Canada site

(https://www.marstar.ca/html/reflibrary/YugoOrdnance/105mmfixedheshtshellm67.html). It was watched on 05/07/2019) containing a housing with a wall thickness decreasing towards the head, a charge of plastic explosive (BB), a bottom fuse, a tracer, a lead device, a ballistic tip. This device works as follows: when meeting with an obstacle, having a supply of kinetic energy, the projectile does not penetrate the obstacle, but flattens along it, so it does not bounce from it and increases the contact area of the warhead and the obstacle. Then the bottom fuse fires, and the detonation compression shock wave propagates from the bottom of the projectile to the warhead, and, consequently, to the obstacle. The shock wave extends beyond the warhead (warhead) and propagates in the obstruction with the speed of sound in the obstruction material along the extension of the projectile axis.

When the compression shock wave reaches the back of the obstacle, a rarefaction wave occurs, propagating in the opposite direction. Because obstacles are made of structural materials, such as concrete and the like, which work well in compression, but poorly in tension, then, under the action of a rarefaction wave, tension is created and spalling occurs on the back of the barrier, which strikes the internal space of the reinforcement with fragments. With a small thickness of the barrier, a round through hole is formed, the diameter of which is approximately equal to the diameter of the contact spot between the warhead and the barrier.

However, in the specified device there is a low efficiency of the explosive charge. The area of spalling from the back of the barrier or the area of the through hole in the case of a small width of the barrier is approximately equal to the area of the contact spot between the warhead and the barrier, since the shock wave front in this device can be considered flat.

Also known is a high-explosive armor-piercing projectile (Deshpande, PU, Prabhu, VD, Prabhakaran, KV (2003) Impulsive loading of armor by high explosive squash head munition // Defense Science Journal 53 (4)), which is a prototype of the proposed utility model containing a casing with a wall thickness decreasing toward the head, a charge of a plastic explosive, a bottom fuse, a lead device, a screwed bottom with tracer elements, an inert filler of the head, and a plug. This device works as follows: when meeting with an obstacle, having a supply of kinetic energy, the projectile does not penetrate the obstacle, but flattens along it, so it does not bounce from it and increases the contact area of the warhead and the obstacle. Then the bottom fuse fires, and the detonation compression shock wave propagates from the bottom of the projectile to the warhead, and, consequently, to the obstacle. The shock wave extends beyond the warhead and propagates in the barrier with the speed of sound in the barrier material along the extension of the projectile axis. When the compression shock wave reaches the back of the obstacle, a rarefaction wave occurs, propagating in the opposite direction. Because obstacles are made of structural materials, such as concrete and the like, which work well in compression, but poorly in tension, then, under the action of a rarefaction wave, tension is created and spalling occurs on the back of the barrier, which strikes the internal space of the reinforcement with fragments. With a small thickness of the barrier, a round through hole is formed, the diameter of which is approximately equal to the diameter of the contact spot between the warhead and the barrier.

However, in the specified device there is a low efficiency of the explosive charge. The area of spalling from the back of the barrier or the area of the through hole in the case of a small width of the barrier is approximately equal to the area of the contact spot between the warhead and the barrier, since the shock wave front in this device can be considered flat.

The objective (technical result) of the proposed utility model is to increase the area of spalling from the back of the barrier or the area of through penetration in the case of a small barrier width.

The task is achieved in that in the known device armor-piercing high-explosive projectile - containing a housing with decreasing wall thickness to the head part, a plastic explosive charge located in it, a driving device, a screwed bottom with a bottom fuse, - the housing consists of a separate cylinder and a ballistic tip, the explosive charge consists of a primary explosive and a lens of explosives, with a higher detonation speed.

In FIG. 1 shows a section of an armor-piercing high-explosive shell; in FIG. 2 is a drawing explaining its operation.

The proposed device comprises a housing made of plastic steel alloy with a decreasing wall thickness (1), the main explosive charge (2), an explosive lens with a higher detonation velocity (3), a bottom fuse (4), a master device (5) , ballistic tip (6), screw-in bottom (7).

The device operates as follows: when a projectile collides with an obstacle, the head of the projectile is flattened, and the projectile has the form shown in FIG. 2. A lens from an explosive having a higher detonation speed (3) takes the form shown in FIG. 2. The bottom fuse (4) fires at time t ₀ at point O. At time t _{1, the} front of the detonation wave reaches point A and will take the form of a part of a spherical surface with radius L2. By time t _{2, the} detonation wave front will reach point B lying on the boundary between the warhead and the obstacle, and then the compression shock wave propagation in the obstacle will begin. By time t _{3, the} front of the shock wave reaches point C and completely goes beyond the warhead. Assuming that the speed of sound in the barrier material is equal to the detonation velocity of the explosive (3), so that the shock wave front passing through point C has a radius of curvature equal to R ₃ at the moment of passage, it is necessary that the condition

or what is the same

Further, this front of a shock wave of large curvature will propagate along an obstacle of thickness H, and when the front of the shock wave reaches the rear of the obstacle, the spall will have a radius R ₀ equal to

and the spall area S ₀ will be equal to

Without an explosive lens with a higher detonation velocity, this radius is

и площадь откола соответственно равна

and the spall area is respectively equal

что приближенно к реальным условиям и соответствует толщине преграды равной 0,4 м, площадь откола в случае снаряда с линзой из ВВ, обладающего более высокой скоростью детонации, в 4 раз больше площади откола снаряда без нее, т.е.

For example, provided

which is close to real conditions and corresponds to a barrier thickness of 0.4 m, the spall area in the case of a projectile with an explosive lens having a higher detonation velocity is 4 times larger than the projectile spall area without it, i.e.

The technical result is to increase the curvature of the front of the shock wave, as a result of which the spall area (or the area of the through hole in the case of a small barrier width) increases.

Claims (1)

An high-explosive armor-piercing projectile containing a body with a wall thickness decreasing towards the head, a plastic explosive charge located inside it, a driving device, a screwed bottom with a bottom fuse, characterized in that the body consists of a separate cylinder and ballistic tip, the explosive charge consists of main explosives and lenses from explosives with a higher detonation speed.

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