RU2326333C2 - Method of firing large-calibre barrel weapons using dummy cartridge and dummy cartridge for its implementing - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: bullet from a live cartridge for smallarms of a smaller calibre is subject to a longitudinal acceleration, which is effectuated over the length of entering the bullet into a case, then powder gases and a portion of propellant charge that has not been burnt down are released into the atmosphere and the bullet is decelerated over the length of a rifled part of the barrel due to the force of friction between the bullet and the rifles to achieve a muzzle velocity for large-calibre barrel weapons. To this end said live cartridge for smallarms forms a gas-generator and a propelled body, whereby a projectile simulator is equipped with a projectile shell simulator for large-calibre barrel weapons. The simulators are attached to each other using a fire indestructible connection. A rifled barrel corresponding to a live smallarms cartridge and being open on its both sides is fixed along the centre line of the projectile and shell simulators. Around said barrel inside the projectile and shell simulators for large-calibre barrel weapons there is a free space connected via a perforation made in the rifled barrel on the edge of the live smallarms cartridge case to the space of the barrel and via a perforation made in the head of the projectile simulator - to the atmosphere.

EFFECT: cheapening the process of gunners training on retention of safety thereof.

4 cl, 4 dwg

Description

The invention relates to military equipment, and in particular to means of training personnel of military units to shoot from large-caliber weapons, for example grenade launchers: hand, barrel, machine-gun automatic, etc.

In the armies of almost all countries, training, training, and training cartridges are used for this purpose (see Jane's Ammunition Handbook Edited by Terry J Cander and Charles Q Cutshaw Ninth Edition 2000-2001, p. 584-588). The difference in the name of these cartridges is purely conditional, because they have almost the same device and purpose, which is to reduce the cost of preparing grenade launchers.

These cartridges, despite the fact that they are much simpler than combat, are still quite expensive, because are disposable and include full-time cartridges of live ammunition and quite complex overall-mass simulators of live grenades. Another disadvantage of these cartridges is that firing them leads to significant wear of grenade launchers, as with each shot there is an interaction of the grenade simulator with the barrel and the impact on the barrel of powder gases having high pressure and temperature.

In most receiver systems, a firing method is implemented in which the initial velocity of the ammunition is communicated by using the pressure of the powder gases at the bottom of the ammunition. In this case, the dispersal of ammunition is carried out continuously along the entire length of the barrel.

This method has found application, including in educational (training) cartridges for grenade launchers M79 and M203.

For example, the German TR-T training cartridge for the M79 grenade launcher (Jane's Ammunition Handbook Edited by Terry J Cander and Charles Q Cutshaw Ninth Edition 2000-2001, p. 588), selected by the authors and the applicant of the present invention with its analogue, contain a standard two-chamber sleeve from a live cartridge and a mass-scale simulator of a military grenade, mounted in a sleeve and including an aluminum case in the form of a glass, a leading belt and a thin-walled head fairing of a hemispherical shape, fastened to the body and covering its front end.

In the sleeve, the capsule and propellant charge are placed in a perforated high-pressure chamber and together with it form a gas generator - a source of powder gases for continuous acceleration of the grenade simulator along the length of the grenade launcher to the muzzle velocity of the grenade equal to 76 m / s.

The disadvantage of the analogue is the complexity of the design, which affects its high cost. Some of the drawbacks of the analog were eliminated in the training cartridge TP for the M203 grenade launcher (Jane's Ammunition Handbook Edited by Terry J Cander and Charles Q Cutshaw Ninth Edition 2000-2001, p.588), selected by the authors and applicant of the present invention with its prototype.

The TP cartridge consists mainly of the same structural elements as the TP-T cartridge, and is distinguished by its simplified design and the absence of a tracer.

The disadvantage of the prototype is that even with a simplified design, it is not cheap enough.

In terms of reducing the cost of the preparation of grenade launchers, the use of small arms live ammunition for this purpose is of considerable interest. their production is massive and, therefore, they have a low cost and stable ballistic characteristics.

Small arms cartridges have a fundamental structural similarity with the training and combat cartridges for grenade launchers and consist of a cartridge case, a capsule and a propelling charge forming a gas generator, and a projectile body - a bullet.

Small arms ammunition bullets have a different shape of the warhead, including very close to the shape of the warhead of the grenade cartridges for grenade launchers. An example of this would be a 9 mm cartridge for a Makarov pistol (see Jane's Ammunition Handbook Edited by Terry J Cander and Charles Q Cutshaw Ninth Edition 2000-2001, p. 34). Using these cartridges, the translational speed of the bullets is reported as a result of their continuous longitudinal acceleration in the gun barrel by the pressure of the powder gases from the combustion of propellant charges. However, due to the significant entry of their bullets into the shells, by the time they leave the shells, they have a speed greater than the muzzle velocity of the grenade cartridges for grenade launchers. For example, for a bullet cartridge for a Makarov pistol, the calculated value of this speed is 120-122 m / s. Obviously, the direct use of this cartridge will require constructive refinement of the grenade launcher sight - this will somewhat increase the cost of preparing grenade launchers, reduce its effectiveness and prevent the use of training grenade launchers for aimed firing of live ammunition for grenade launchers.

The technical task of the present invention is to eliminate the disadvantages of the known training, training and training cartridges for large-caliber weapons, namely reducing the cost of the shot and eliminating the impact of factors of firing a cartridge on the large-caliber weapon, which will reduce the cost of training shooters.

According to the present invention, the solution to the problem is achieved:

- in terms of the method of firing a training cartridge from a large-caliber barrel weapon, including longitudinal acceleration of a missile body by the pressure of powder gases, by the fact that a bullet of a small-caliber small arms combat cartridge is subjected to longitudinal acceleration, the acceleration is carried out at the length of the bullet entering the sleeve, and then dropped from shells of powder gases and an unburned propellant charge into the atmosphere also inhibit the bullet along the length of the threaded portion of the barrel by the force of its friction against its rifling to the muzzle velocity of the projectile for the barrel heavy weapons;

- in terms of a training cartridge for a large-caliber barrel weapon containing a gas generator, a missile body and a dimensional simulator of a projectile, in that the gas generator and missile body are formed by a live cartridge of a small arms, while the projectile simulator is equipped with a shell sleeve simulator that is indestructible when fired during firing for a large-caliber weapon, along the axis of the shell and shell simulators, a corresponding small arms live cartridge and a rifled barrel open on both sides are fixed around a free cavity is formed in the shell and shell simulators for the large-caliber weapon; a latch of a small arms live cartridge mounted that holds the bottom of its sleeve in the plane of the bottom of the sleeve simulator is mounted, and the length of the threaded portion of the small arms barrel is made to provide braking bullets of a small arms combat cartridge up to the muzzle velocity of a projectile for a large-caliber barrel weapon.

In special cases:

- the perforation in the rifled barrel is formed by the end gap between its chamber and the threaded part, while the chamber is made directly in the simulator of the shell for the large-caliber weapon, and the threaded part of the barrel in the front part is fastened to the shell simulator for the large-caliber weapon and provided with external front end gap radial protrusions installed in the end cavity, made in the simulator of the shell of the shell for a large-caliber weapon;

- the latch of the small arms combat cartridge is made of a spring wire having a radius less than the depth of the annular groove on the sleeve of the small arms combat cartridge, in the form of a U-shaped bracket, the distance between the ends of which is equal to or less than the diameter of the annular groove and which is located between the bottom of the end recess made in the bottom of the shell shell simulator for a large-caliber weapon, and a lid fixed therein, provided with a through axial hole having a diameter equal to or slightly larger than the diameter of the bottom of the shells zy of a small arms combat cartridge, in a reciprocal cavity retainer, the parallel grooves of which are symmetrically relative to the through axial hole in the cover and at a distance from each other equal to the distance between the ends of the retainer, while the width of the parallel cavity grooves is greater than the sum of the diameter of the U-shaped bracket wire and the depth of the annular groove, the depth equal to the diameter of the wire of the U-shaped bracket, the thickness of the lid above the cavity equal to the distance from the bottom of the sleeve of the live cartridge of the small arms to the annular avki on it, and the length of the ends of the U-shaped bracket - providing accommodation for their ends loop holes in the lid.

The essence of the invention is illustrated in the drawing, in which Fig. 1 shows a training cartridge in a section, Fig. 2 is a section along A-A in Fig. 1, Fig. 3 is a section along BB in Fig. 1 and in Fig. .4 - callout B in figure 1.

The training cartridge for a large-caliber barrel weapon, for example, a grenade launcher, consists of a hollow grenade simulator 1 and a sleeve simulator 2 screwed into it, which give it a shape corresponding to the shape of a live cartridge for a grenade launcher, and in which its other structural elements are made and placed.

On the axis of both simulators there is a small arms barrel formed by a chamber 3 made in a shell simulator 2 and ending on a cut of a cartridge case 4 of a small arms cartridge 5 with an end cavity 6 made in the shell simulator and a threaded barrel part 7 screwed into the threaded hole 8 made at the bottom of the hollow grenade simulator 1, with the formation of an end gap 9 having the maximum possible length provided that the head streamlined part of the bullet 10 b is placed between its end and the bottom of the end cavity 6 in the simulator of the sleeve 2 oy cartridge 5 small arms in the threaded portion 7 of the barrel. On the outer surface of the threaded part of the barrel, which enters the end cavity 6, there are made radial protrusions 11 by which they are centered in this cavity. At the bottom of the grenade simulator 1, perforation holes 12 are made around the threaded hole 8, connecting the cavity of the grenade simulator with the atmosphere.

The live cartridge of small arms 5 (in this case, a 9 mm cartridge for Makarov’s pistol) consists of a sleeve 4 having an annular groove 13 on the outer surface near its bottom, and a bullet 10 recessed into the sleeve by a value of 14, between which a propellant charge 15 . In the bottom of the sleeve 4 is placed a shock capsule, gasdynamically associated with a propelling charge 15.

The live cartridge 5 of the small arms is secured against longitudinal movements in the chamber 3 by a latch 16 having the shape of a U-shaped bracket made of a spring wire and placed at its ends in the annular groove 13 of the sleeve 4, while:

- the latch 16 is placed in the reciprocal cavity formed by the bottom of the end recess 17 in the bottom of the sleeve simulator 2 and the cover 18 with a through axial hole having a diameter slightly larger than the diameter of the bottom of the sleeve 4, and three grooves made in the cover 18:

- two parallel grooves 19 under the ends 20 of the latch 16, intersecting the cover 18, located symmetrically to the chamber 3, at a distance from each other equal to or slightly smaller than the diameter of the annular groove 13 of the sleeve 4, having a depth equal to the diameter of the wire from which the U-shaped the bracket, and a width of 21 is greater than the sum of the diameter of this wire and the depth of the annular groove 13 on the sleeve 4;

- the third groove 22 under the shelf 23 of the U-shaped bracket connecting the grooves 19 on one side of the lid 18 at its edge;

- the thickness of the cover 18 above the grooves 19 and 22 is made equal to the distance from the annular groove 13 to the bottom of the sleeve 4;

- the wire of the U-shaped bracket has a radius less than the depth of the annular groove 13 on the sleeve 4, and the ends 20 of the bracket are made in length, providing the placement of their ends beyond the contour of the axial hole in the cover 18.

Work with a training cartridge includes loading it with a live cartridge of 5 small arms, loading a grenade launcher with a training cartridge, firing a shot, extracting a training cartridge from a grenade launcher, and removing sleeve 4 from a training cartridge.

The live cartridge 5 is loaded with small arms by its hand exertion along arrow G, while the front rounded part of the bullet 10 elastically extends the ends 20 of the latch 16 within the width of 21 grooves 19, and when combined with the annular groove 13 on the sleeve 4 of the cartridge 5, they are under the action of elastic forces enter the annular groove 13 and securely hold the cartridge 5 with the bottom of its sleeve 4 in the cavity of the bottom of the simulator of the sleeve 2.

The loading of a grenade launcher with a training cartridge is determined by its design and is carried out in the same way as a live cartridge for a grenade launcher.

Shooting from a grenade launcher using a training cartridge involves cocking a firing device of the grenade launcher, pointing the grenade launcher through its sight at the target and pulling the trigger, while:

- from the impact of the striker of the firing mechanism of the grenade launcher, the capsule of the cartridge 5 is activated and ignites its propellant charge 15;

- when the pressure in the sleeve 4 is greater than the forcing pressure, the bullet 10 begins to accelerate to the rifled part 7 of the small arms barrel and, on the path 14 equal to its entry into the sleeve 4, accelerates, as noted above, to a speed of 120-122 m / s and at the same time crashes into rifling of a small arms barrel in its rifled part 7;

- after the rear end of the bullet 10 from the sleeve 4 exits, the powder gases and the unburned part of the propellant charge 15 are discharged into the end cavity 6, then into the cavity of the hollow grenade simulator 1, and from it through the perforation holes 12 into the grenade launcher, the pressure of the powder gases drops sharply , the unburned part of the propellant charge 15 goes out, and the bullet 10 continues to move by inertia along the threaded part 7 of the barrel;

- when the bullet 10 moves along the threaded part 7 of the barrel, it friction between it and the rifling is decelerated to the muzzle speed of the grenade of the live cartridge for the grenade launcher and flies through the barrel of the grenade launcher to the target.

The necessary braking of the bullet 10 can be provided in various known ways: the length of the threaded part 7 of the barrel, or the pitch (steepness) of its rifling, or the diameter of the channel of the threaded part 7 of the barrel, or the number of rifling in it, or the depth of the rifling, etc.

Removing the training cartridge from the barrel of a grenade launcher is determined by the design of the latter and is carried out in the same way as a fired cartridge case of a live cartridge for a grenade launcher.

Removing the sleeve 4 from the chamber 3 after firing is made by pushing it along the arrow D, for example, with a ramrod for cleaning the barrel of a small arms corresponding to cartridge 5, while the sleeve 4 is elongated by the bevel of its annular groove 13, unloads the ends 20 of the retainer 16 and leaves the chamber 3, and the ends 20 after exiting from them, the liners under the action of elastic forces return to their original position.

From the description of the device and the work of the training cartridge, it can be seen that with its use:

- without a live cartridge for small arms, it is possible to conduct continuous training, following one after another, the loading of the grenade launcher, cocking the shock mechanism of the grenade launcher, pointing it at the target, pulling the trigger and reloading the grenade launcher, and this process will be absolutely safe for the trained grenade launcher and the people around him;

- using a live cartridge for small arms:

- the cost of one shot is almost equal to the cost of a small arms live cartridge, because the stability of the barrel of small arms is several tens of thousands of shots;

- there is no harmful effect of powder gases having high temperature and pressure on the surface of the bore of the grenade launcher, because there are few of them and they, before getting into the barrel of the grenade launcher, preliminarily expand greatly in the cavity of the training cartridge and, therefore, their pressure and temperature are significantly reduced;

- there is no wear of the barrel of the grenade launcher from friction along its channel and the rifle of the grenade simulator.

In addition, the proposed device can be used in multiply charged (magazine) systems as a first (sighting) shot, so that for subsequent shots, if necessary, to make corrections both in the training process and in combat operations.

Claims (4)

1. A method of firing a training cartridge from a large-caliber weapon, including longitudinal acceleration of a missile body by the pressure of powder gases, characterized in that a bullet of a small-caliber combat cartridge is used as a missile body, the acceleration of which is carried out at the length of the bullet entering the cartridge case, after which release powder gases from the sleeve, and the unburned propellant charge into the atmosphere, and brake the bullet along the length of the threaded portion of the barrel by friction against the barrel rifles to a speed equal to the muzzle Noah skrosti projectile for barrel caliber weapons. 2. A training cartridge for a large-caliber barrel weapon containing a gas generator, a missile body and a dimensional projectile simulator, characterized in that the gas generator and a missile body are formed by a small arms combat cartridge, while the projectile simulator is equipped with a shell shell simulator that is indestructible when fired during firing. for a large-caliber barrel weapon, along the axis of the shell and shell simulators, a corresponding small arms live cartridge and an rifled barrel open on both sides, secured in which a free cavity is formed in the simulators of a shell and shell case for a large-caliber weapon; a sleeve simulator mounted a latch of a small arms live cartridge that holds the bottom of its sleeve in the plane of the bottom of the sleeve simulator, the threaded portion of the small arms barrel is provided with a length that provides braking of a bullet of a small arms live cartridge to the muzzle velocity of a projectile for a large-caliber barrel weapon. 3. The cartridge according to claim 2, characterized in that the perforation in the rifled barrel is formed by the end gap between its chamber and the threaded part, the chamber being made directly in the simulator of a shell for a large-caliber weapon, and the threaded part of the barrel in the front part is fastened with a simulator a projectile for a large-caliber barrel weapon and in front of the end slit is made with external radial protrusions installed in the end cavity of the shell shell simulator for a large-caliber barrel weapon. 4. The cartridge according to claim 2 or 3, characterized in that the latch of the small arms live cartridge is made of a spring wire having a radius less than the depth of the annular groove on the sleeve of the small arms live cartridge, in the form of a U-shaped bracket, the distance between the ends of which is equal to or smaller than the diameter of the annular groove and which is located between the bottom of the end recess, made in the bottom of the simulator shell shell for a large-caliber weapon, and fixed in it with a lid equipped with a through axial hole having a diameter equal to or a slightly larger diameter of the bottom of the sleeve of the live cartridge of a small arms, in the cavity response mating device, the parallel grooves of which are located symmetrically relative to the through axial hole in the lid and at a distance from each other equal to the distance between the ends of the holder, while the width of the parallel cavity grooves is greater than the sum of the diameter the wire of the U-shaped bracket and the depth of the annular groove, the depth equal to the diameter of the wire of the U-shaped bracket, the thickness of the lid above the cavity is equal to the distance from the bottom of the sleeve of the combat cartridge firearms and to the annular groove therein, and the length of the ends of the U-shaped bracket provides accommodation their ends behind the contour holes in the lid.

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