RU40462U1 - Arrow-shaped armor-piercing shell - Google Patents

Abstract

Arrow-shaped armor-piercing projectile containing a heavy-alloy core with a tail feather that is mounted in an aluminum sector tray equipped with a plastic leading girdle and a tip with longitudinal grooves, characterized in that the head part of the heavy-alloy core closed by a ballistic fairing, the surface of which is made of a helix, has a stepped shape, in the front end of the pallet has a central funnel with distributed through channels, in the annular groove of which a stopper is installed a sleeve with jumpers of weakened cross-section, and a thin-walled tip with a pallet is geometrically closed by means of a lock connection, while the ratio of the diameter to the length of the head stage of the heavy alloy core and the core diameter is 0.5-0.7, and the heavy alloy core with the sector tray are connected by left-hand thread .

Description

The utility model relates to ammunition, and more specifically, to swept sabot shells with a rigidly fixed tail, using pallets.

The prior art in this area is characterized by a sub-caliber projectile, in the pallet of which a heavy-alloy core with a tail plumage is installed, closed by a caliber tip equipped with longitudinal grooves that form a weakened section for destruction by centrifugal rotation forces of the projectile obtained in the rifling of the barrel of the weapon by means of a leading belt fixed to the pallet ( see US patent 4142467, F 42 In 13/16, 1979).

A sleeve is mounted in the cartridge groove of the bogie part of the pallet by crimping the barrel, in which the receiver of the pallet is placed, which communicates with the volume of the ballistic tip for their separation by excessive pressure of the propellant gases of the propellant charge.

The tip of the core behind the muzzle of the weapon barrel is destroyed along the longitudinal grooves under the action of torque from the rotation of the projectile.

Sub-caliber armor-piercing, the core is longitudinally stable on the trajectory of an autonomous flight to the target, the projectile as a whole is Functionally reliable.

The disadvantage of the described projectile is the relatively low armor penetration due to the large loss of propelling impulse on the ballast mass of the metal tip and the extended pan, which reduces the initial speed of the shortened core.

The more perfect is the armor-piercing subcaliber projectile of a 30 × 173 mm cartridge (RSM 287) for the USA MK44 Chain Gun (Jane`s Ammunition Handbook, 2001-2002, p.103), selected by technical nature and the number of matching features as the closest

analogue to the proposed projectile.

The arrow-shaped heavy alloy core with a pointed aerodynamic head has a rigidly mounted tail aluminum tail placed in a powder propellant charge, which allows to increase the core length and its initial speed to increase armor penetration.

The core is mounted on an abutment in an aluminum pallet having longitudinal cuts, on which are mounted a plastic leading girdle and a tip open from the head end, in which the core is placed with an annular gap.

The tip, the pallet and the lead, the belt are destroyed radially into parts under the influence of the incoming air flow and the centrifugal forces of rotation of the projectile with relatively smaller losses of kinetic energy.

However, a disadvantage of the known projectile is the tendency to ricochet the core when approaching the barrier at angles that exceed normal, which is almost more likely.

In addition, due to the aerodynamic nature of the separation of the ballistic tip, the pallet and the driving belt, a noticeable deceleration of the projectile at a distance of 300 m occurs at once, which reduces the initial core speed and the effectiveness of its main damaging effect.

The objective to which the present utility model is directed is to increase the effectiveness of an armor-piercing arrow-shaped projectile.

The required technical result is achieved in that in the well-known arrow-shaped armor-piercing projectile containing a heavy alloy core with a tail feather, which is mounted in an aluminum sector tray equipped with a plastic leading belt and a tip with longitudinal grooves, at the suggestion of the authors,

the head part of the heavy-alloy core closed by a ballistic fairing, the surface of which is screwed, has a stepped shape, in the front end of the pallet there is a central funnel with distributed through channels, in the annular groove of which there is a locking sleeve with jumpers of weakened section, and a thin-walled tip with a pallet is geometrically closed by lock connection, and the core with the sector tray are connected by means of a left-hand thread, and the ratio of the diameter of the head stage t the iron core to its length and to the diameter of the core is 0.5-0.7.

Distinctive features serve to increase the armor penetration of a projectile at farther distances and meeting angles with a target.

The fairing on the head step of the core creates an aerodynamic shape, which reduces the speed loss from braking on the flight path, and therefore increases the armor penetration.

The helical surface of the core, having an opposite direction to the cuts of the barrel channel, provides longitudinal rigidity of the mount with the pallet during firing, making solidity due to their kinematic closure. When meeting the obstacle, the external thread of the core serves as a localizer, the discrete step-by-step crushing of which reduces the penetration rate and prevents the destruction of the core piercing the thicker obstacle.

The stepped shape of the head of the core eliminates the rebound at large meeting angles with the goal, which expands the functionality of the ammunition.

The implementation of the central funnel in the front end of the sector pallet provides automatic destruction of the locking sleeve by the free flow of air and the dynamic separation of the pan sectors from the swept core.

Through channels made in the sectors of the pallet, the penetration of powder gases of the burning propellant charge into the plastic thin-walled tip, loading it with excessive pressure, which simplifies the separation of the tip along the longitudinal grooves by centrifugal forces of rotation of the projectile into parts when leaving the bore.

After the destruction of the tip, the oncoming air flow actively directly affects the sector tray through its central funnel.

The locking ring sleeve acts as a bandage, geometrically locking the pallet sectors into a functional unity.

Jumpers of a weakened locking sleeve facilitate automatic separation of the pallet sectors under the influence of aerodynamic braking of the incoming flow to separate it from the core.

Making the plastic tip thin-walled reduces the kinetic loss of its destruction and allows the use of springy properties for the lock connection with the pallet, which is structurally simple and technologically advanced.

The claimed range of geometric relations of the diameter (d) of the head stage to its length (1) and to the diameter (D) of the armor-piercing core is optimized and experimentally tested as a localizer of fracture stresses to separate the head stage when it is introduced into the barrier and the bulk of the penetrating core is kept intact, which is aimed at increasing armor penetration.

When the d / D and d / 1 ratios are less than 0.5 or greater than 0.7, the localizer effect degenerates, which leads to an increase in the rate of armor penetration and a decrease in the target damage distance, comparable with these core characteristics without a localizer.

At the front end of the pallet 7 there is a plastic tip 13 connected by protrusions to each other in the lock 14. The thin-walled tip 13 has longitudinal grooves 15 distributed over the surface, weakening its cross section.

The above-described projectile by the hinged part of the pallet 7 is pressed into the sleeve of the sleeve 16 (FIG. 2), which is pressed into the groove that protects it, while part of the core 1 with the plumage 2 is placed inside the propellant propellant charge 17.

In the bottom of the sleeve 16, an igniter capsule 18 is installed with an axial fire transfer tube 19, which is in the propellant charge 17.

The shell operates as follows. When fired by a pulse from the igniter capsule 18, a propellant charge 17 is ignited from the center from the center of the transfer tube 19, during combustion of which inside the sleeve 16 the pressure of gaseous products increases sharply, some of which breaks through the belt 8 and then passes through the channels 12 inside the tip 13, boost.

The powder gases generated during the combustion of the propellant charge 17 ignite the pyrotechnic composition of the tracer 5, the combustion products of which are consumed through the gas-dynamic hole of the washer 6.

The pressure of the powder gases on the pallet 7, the projectile is removed from the sleeve 16, receiving axial rotation when passing through the rifling channel of the barrel of the weapon through the leading belt 8, forming a screw pair.

Rigidly connected to the pallet 7 (thread of the opposite direction to the cuts of the barrel of the weapon), the core 1 receives linear acceleration.

Behind the muzzle of the gun barrel ballistic tip 13

under the action of pressurization to centrifugal forces, the rotation of the projectile is destroyed along the grooves 15, releasing the ballistic fairing 3 and the pallet 7.

By the pressure of the incoming air flow on the central funnel 11 and the torque of the projectile rotation, the ring 9 is destroyed along the weakened jumpers, as a result of which the sectors of the pallet 7 are wedged and break the leading belt 8 along the jumpers from the rifles formed in the barrel.

Next, the swept core 1 on the trajectory flies autonomously, longitudinally oriented by the tail feather 2, through which the center of pressure is displaced beyond the center of mass.

When meeting with the target, the cowl 3 is crushed, and the core 1 with the head stage 4 "bites" the metal of the obstacle and turns in the opposite direction to the normal position. In this case, the step 4 breaks off, localizing the transverse loads, and the core 1 dynamically penetrates the obstacle, punching it.

Claims (1)

Arrow-shaped armor-piercing projectile containing a heavy-alloy core with a tail feather that is mounted in an aluminum sector tray equipped with a plastic leading girdle and a tip with longitudinal grooves, characterized in that the head part of the heavy-alloy core closed by a ballistic fairing, the surface of which is made of a helix, has a stepped shape, in the front end of the pallet has a central funnel with distributed through channels, in the annular groove of which a stopper is installed a sleeve with jumpers of weakened cross-section, and a thin-walled tip with a pallet is geometrically closed by means of a lock connection, while the ratio of the diameter to the length of the head stage of the heavy alloy core and the core diameter is 0.5-0.7, and the heavy alloy core with the sector tray are connected by left-hand thread .