RU2354917C1 - Shot for grenade launcher - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: invention is related to weapons for anti-personnel automatic grenade launchers. Shot contains fragmentation grenade, tail of which is located in mouth of cartridge, in which receiver is arranged and transverse diaphragm is installed with gaskets above missile. Through grooves of tail are inclined backwards at the angle of 15-35° relative to longitudinal axis, with radio of total area of their cross section to grenade midship in the range of 9-16%. These grooves perform functions of aerodynamic rudders that automatically additionally turn longitudinal axis of grenade in approach flow of air to flight trajectory, which increases close grouping of shots.

EFFECT: increased grouping of shooting.

2 dwg

Description

The invention relates to ammunition for anti-personnel automatic grenade launchers and can be used in the manufacture of artillery rounds of unitary loading of small caliber for firing at large casting angles with enhanced combat accuracy.

The level of this technical field characterizes a small-caliber shot to an automatic grenade launcher according to patent RU 2196294, F42B 12/24, 2003, the projectile of which has an aerodynamic shape formed by a streamlined configuration fuse head and a shoulder part of the protrusion made in the form of a truncated cone, tapering backwards, the length of which is 0.7-0.9 caliber grenades.

The angle of inclination of the generatrix of the conical shank having an open bottom cavity is optimized in the range of 8-10 °.

The bottom cavity of the grenade communicates with the atmosphere through through slots on the conical surface of the shank, through which the air of the incoming flow penetrates inward, reducing the aerodynamic drag of the grenade along the flight path to the target.

The described improvements in the design and shape of the grenade provided at subsonic flight speeds an increment in range of 20%.

The grenade body filled with explosive is equipped with a copper lead belt, which is pressed into the radial groove.

A characteristic feature of the described grenade is the regulated crushing of the thickened body by means of a grid of corrugations made on its inner surface. Intersecting corrugations form weakened sections of the body wall and, forming gas wedges from the products of detonation of the filling, serve as stress concentrators along which, basically, it is destroyed into fragments of a given mass and shape.

A continuation of the advantages of the described grenade is the inherent design flaws, determined by the presence of a cavity in the conical shank, which practically does not crush into the damaging elements of the required size. At the same time, the combat power of the grenade is reduced due to a decrease in explosive filling.

The noted shortcomings are excluded in the design of the grenade of the small-caliber artillery cartridge according to the patent 2087837, F42B 5/02, 1997, which, for most of the matching features, was chosen as the closest analogue of the proposed shot to the grenade launcher.

A well-known artillery cartridge includes a fragmentation grenade containing explosive filling, a copper lead belt and a rectangular-shaped shank with longitudinal through grooves for air to escape from the barrel of the cartridge case when the grenade is pressed to fit onto the mating sleeve of the cartridge case.

The following are mounted in the sleeve: an igniter capsule, propellant powder charge and a diaphragm with 0.05 mm thick burning foil gaskets. The diaphragm has calibrated communication holes for the expiration of propellant gases during the firing of a propellant charge into the receiver, formed between the end face of the grenade and the diaphragm of the sleeve.

The diaphragm with gaskets is rigidly connected to the sleeve by means of a geometric closure of the material of the annular notch of the reference ledge in the sleeve of the sleeve. In this case, the diaphragm presses and fixes the propellant charge in the sleeve through the lower gasket.

The upper gasket on the diaphragm during cartridge assembly prevents the transfer of compressed air pressure to the propellant powder charge, which is removed from the receiver through the longitudinal grooves of the grenade shaft.

A grenade with a sleeve is connected by compressing the last muzzle in the sunset groove of the shank, forming the constructive unity of the unitary shot to the grenade launcher.

In the well-known artillery cartridge, a propelling impulse is structurally stabilized, which ensures identical initial grenade velocities during firing and increases the firing range.

However, the disadvantage of the known artillery cartridge for the grenade launcher is the poor accuracy due to the relatively large spread in range, which is determined by the unstabilized spatial position of the longitudinal axis of the grenade relative to the flight path.

An arbitrary angle of attack of grenades on the trajectory determines various aerodynamic braking and, as a result, a large spread in range, which reduces the main damaging effect of fragmentation grenades.

The problem to which the present invention is directed is the constructive improvement of the grenade artillery shot, providing a comparable initial speed, to increase the accuracy of fire while maintaining the average flight range of grenades.

The problem is solved in that the shot for the grenade launcher contains a fragmentation grenade with explosive filling and a copper lead belt, installed by a shank, in which through grooves distributed along the perimeter are made, in the sleeve of the sleeve, in which the transverse diaphragm with gaskets is located to form the receiver, under which the propellant is placed powder charge in communication with the igniter capsule. The through grooves in the shank are inclined backward at an angle of 15-35 ° relative to the longitudinal axis, with a ratio of the total cross-sectional area to the grenade midsection in the range of 9-16%.

The longitudinal through grooves of the grenade shank of the proposed shape and size perform the functions of aerodynamic rudders, which automatically in the incoming air flow turn the longitudinal axis of the grenade to the flight path, which significantly reduces the range dispersion.

When the angle of inclination of the longitudinal through grooves back relative to the longitudinal axis of the grenade is less than 15 °, the formation of sufficiently compressed air jets that stably affect the spatial position of the grenade along the flight path is not ensured.

In the longitudinal through grooves of the shank with a backward inclination of more than 35 °, the free flow is disrupted, as a result of which the formed compressed air jets are carried away into the boundary layer, i.e., the control aerodynamic connection with the grenade is broken.

Practical firing established the optimal ratio of the total cross-sectional area of the longitudinal through grooves distributed along the perimeter of the grenade shank with its midsection, providing a significant increase in the accuracy of fire.

With the indicated area ratio less than 9%, the accuracy of fire is lower than that of regular grenades.

With an area ratio of more than 16%, the accuracy of fire decreases by half and then drops sharply.

In the optimal range of the ratio of the total cross-sectional area of the longitudinal through grooves to the midship of the grenade shaft, the accuracy in range is 5-6 times higher than in the prototype, while the absolute firing range is slightly reduced due to aerodynamic braking on the control pulses of the rudders (grooves), but remains higher than the average range of regular grenades.

Therefore, each essential feature is necessary, and their combination in a stable relationship is sufficient to achieve a novelty of quality that is not inherent in the characteristics of disunity, that is, the technical problem posed in the invention is solved not by the sum of the effects, but by a new super-effect of the sum of the attributes.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the invention does not explicitly follow for an ammunition specialist, showed that it is not known, and taking into account the possibility of industrial serial production of artillery rounds for a grenade launcher of the claimed design, it can be concluded that the criteria are met patentability.

The invention is illustrated by drawings, which depict: in figure 1 - the proposed shot to the grenade launcher; figure 2 is a section along aa in figure 1.

A shot for a grenade launcher (Fig. 1) contains a grenade 1 with explosive filling 2 and a sleeve 3 equipped with a propellant powder charge 4 in communication with the central igniter 5.

The grenade 1 is equipped with a head fuse 6 and a copper lead belt 7, pressed into the radial groove of the body 8 of the grenade 1.

On the shank of the grenade 1 (gland), there are made longitudinal through grooves 9 distributed along the perimeter (Fig. 2), which are inclined backward at an angle of 15-35 ° to the longitudinal axis. The total cross-sectional area of the longitudinal through grooves 9 (the optimal number of 4 pieces) is 9-16% of the midship of grenade 1.

A grenade 1 with a press-fit shank is installed on the ledge of the sleeve 3, formed by its dulcate, mating with the shank of the grenade 1, while the muzzle of the sleeve 3 is pressed into the sunset grooves of the housing 8 on the shank, forming their castle connection.

The propellant powder charge 4 is covered with a transverse diaphragm 10 with calibrated through holes 11 closed on both sides by burning gaskets of metal foil (not shown conventionally in the drawings).

The diaphragm 10 with gaskets by means of a stamping tool is geometrically closed in the body of the sleeve 3, hermetically blocking the powder charge 4.

The diaphragm 10 is mounted with a guaranteed clearance from the step of the sleeve 3, forming a free volume - receiver 12 for the accumulation of powder gases during combustion of the charge 4.

When assembling a grenade 1 with a sleeve 3, the compressed air in the muzzle of the latter freely enters the atmosphere through the through longitudinal grooves 9; the upper gasket is pressed against the diaphragm 10, preventing deformation of the charge 4 and the separation of its lower sealing gasket. Thus, the integrity and tightness of the structural connection of the diaphragm 10 with the sleeve 3 is preserved during storage and in official use, ensuring stable operation during firing.

When firing, the heat pulse from the igniter capsule 5 sets fire to the propellant charge 4, the stable combustion of which is ensured by high pressure in the volume limited by the sealed diaphragm 10.

The products of combustion of the propellant propellant charge 4 burn the foil of both gaskets of the diaphragm 10 and jet through calibrated holes 11 enter the receiver 12 of a much larger volume, where the gas pressure drops to the worker, which will throw a grenade 1 with a calculated initial speed for a given range.

In the receiver 12, the powder gases accumulate and mix, while smoothing out the inevitable fluctuations in the pressure of the transition process of the onset of combustion and from the difference in volume in the so-called low pressure chamber (receiver 12).

Further, under the action of the developing pressure of the powder gases, the sleeve 3 is separated with a grenade 1, which, rotating, moves along the barrel of the grenade launcher.

The proposed design of the artillery shot provided identical parameters and geometric ratios of the structural elements of mass-produced products, which stabilizes the functioning, initial speed and propelling impulse.

On the flight path, the longitudinal axis of the grenade 1 is automatically reactively corrected by the control pulses of the compressed air jets formed in the inclined through grooves 9 of the shank directed toward the center, creating an aerodynamic imbalance opposite to the deviation of the longitudinal axis of the grenade. As a result of this, compared with the prototype, the accuracy of fire increased by a factor of 5-6 due to a corresponding decrease in range dispersion.

The proposed shot for a grenade launcher does not change its service indicators during long-term storage, ensuring the impermeability of atmospheric moisture to the propellant propellant charge, the rigid attachment of structural elements in a stable functional relationship for identical initial shooting conditions.

The proposed simple technical improvements to the design of the grenade, without changing the overall dimensions of the standard artillery shot, made it possible to increase the efficiency of the fragmentation effect of the grenade by increasing the accuracy of fire.

The invention allows to modernize existing ammunition through mechanical refinement of the shank of a grenade, providing an increase in the main indicators of purpose.

Claims (1)

A shot for a grenade launcher containing a fragmentation grenade with explosive filling and a copper lead belt, mounted by a shank, in which through grooves distributed along the perimeter are made, in a sleeve barrel, in which there is a transverse diaphragm with gaskets forming a receiver, under which a propellant powder charge is communicated, communicating with an igniter capsule, characterized in that the said through grooves are inclined backward at an angle of 15-35 ° relative to the longitudinal axis, with a ratio of their total area cross-section to the midsection of a grenade in the range of 9-16%.

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