RU201079U1 - Disposable grenade launcher - Google Patents

Abstract

The utility model relates to the field of military technology, namely, single-use grenade launcher or flamethrower shots. The grenade launcher consists of a launcher, closed with sealed covers from the breech and muzzle cuts, grenades sequentially placed in it, a rocket engine, including a chamber with a launch charge and a gas-water channel installed in it, as well as a block of inert mass with technical liquid installed in the launch device up to the stop in the cut of the gas-water channel, made in the form of a single-nozzle conical block, compressed by a compensating ring. The technical liquid in a sealed package is placed in the annular volume of the inert mass block formed by the outer cylindrical shell, the inner gas outlet sleeve and annular plugs entering the grooves made at the ends on the outer surface of the gas outlet sleeve, and the inner diameter of the gas outlet sleeve d is (0.2. ..0,6) D, where D is the caliber of the grenade. The gas outlet sleeve is used to ensure the jet flow of the starting charge combustion products and to exclude the blocking of the starting charge combustion products in the starting device. In this case, the cylindrical shell, plugs and gas outlet sleeve are made of a material easily destroyed by a gas flow, impregnated with a film-forming solution. The utility model provides increased safety of the shooter when firing from semi-closed positions and premises while reducing the mass of the grenade launcher and increasing the muzzle velocity of the grenade.

Description

The utility model relates to the field of military technology and can be used in the design of ammunition intended for firing "from the shoulder", for example, single-use grenade launcher or flamethrower shots.

One of the main requirements for the development of this type of weapon is to ensure the safety of the shooter in the process of firing while minimizing the mass of the entire grenade launcher and maintaining the muzzle velocity. These requirements are especially stringent when shooting from semi-closed positions and from indoors.

The process of firing is accompanied by the outflow of a jet of high-temperature gases into the environment from the breech cut of the launcher of the grenade launcher, the action of which leads to a significant increase in pressure and temperature. The resulting shock wave forms a field of impulse excess pressures (IDP), which negatively affects the pointer. Exposure of the shooter to a high level of IID may result in painful sensations to the hearing organs and injury to internal organs. Therefore, there are a large number of technical solutions aimed at reducing the impact of negative factors on the operator during the firing process.

Known technical solution (Weapons of modern infantry: an illustrated guide. Part II / S.L. Fedoseev. - M .:
Astrel Publishing House LLC: AST Publishing House LLC, 2001. - 256 p .:
silt - (Military equipment), p. 180), providing for the placement of an expelling powder charge between the grenade and the counterweight. This technical solution is implemented in the AT4 CS grenade launcher of the Swedish company SAAB BoforsDynamics and the American corporation ATK, consisting of a barrel, a grenade, an anti-mass - a small amount of non-freezing non-combustible liquid in a destructible container and a starting expelling powder charge located in the barrel between the grenade and the anti-mass. At the moment of firing, the products of combustion of the propelling charge simultaneously push the grenade towards the muzzle, and the liquid towards the breech, while the liquid is partially ejected from the side of the breech in the form of splashes, and partially evaporates, thereby significantly reducing the exhaust of powder gases.

This technical solution allows you to reduce the danger zone formed when firing behind the breech of the grenade launcher, which opens up the possibility of firing from closed, cramped rooms. However, the disadvantage of this design of the grenade launcher is the increased mass of the grenade launcher due to the loading of the barrel with high pressure of powder gases when fired. Therefore, to ensure safe firing, it is necessary to increase the wall thickness of the grenade launcher. Another disadvantage is the increased length of the launch tube due to the need to provide a virtually double muzzle path - directly for accelerating the grenade and for counter-mass moving in opposite directions in the barrel bore.

Known grenade launcher (patent RU2317505С1 dated 05/29/2006 "Method of firing a grenade and a grenade launcher for its implementation"), consisting of a barrel, a grenade, a starting charge and counter-mass. In the aft part of the grenade body, a high-pressure chamber is installed, in which the starting charge is placed, and a cylindrical nozzle, with a counter-mass placed in it. In this case, the volume between the bottom of the grenade and the counter-mass communicates with the high-pressure chamber by means of gas-water channels formed in the body of the high-pressure chamber. The disadvantage of this design of the grenade launcher is the large mass and longitudinal-dimensional characteristics of the grenade in the combat position, due to the presence of counter-mass, similar in mass to the grenade, and an increase in passive mass on the trajectory due to the presence of a cylindrical nozzle attached to the grenade and previously used to place the counter-mass, as well as a decrease in the muzzle velocity of the grenade, and, consequently, the aiming range due to the replacement of the nozzle with gas-water channels, the use of which reduces the speed of the gas flow.

The closest analogue of the proposed utility model is the design of the grenade launcher (patent RU173217U1 dated 11/29/2016 "Grenade launcher with a high-pressure chamber with a nozzle perforation of the radial-axial dispersion of the combined reaction inert mass"), which includes a starting device, a grenade, a starting engine, implemented in in the form of a high-pressure chamber containing a starting charge, a cylindrical nozzle placed in the aft part of the grenade and containing a combined reaction inert mass (RIM), consisting of free-flowing and liquid inert masses. This technical solution provides a reduction in the sound level of the shot. However, replacing the nozzle unit with gas-water channels leads to a drop in the flow rate of the gas jet, engine thrust, and, consequently, the muzzle velocity of the grenade.

Also, when firing, there is a danger of locking the combustion products of the starting charge in the inner volume of the high-pressure chamber between the front bottom and the end of the RIM, leading to the destruction of the cylindrical nozzle. Another disadvantage is the presence of free-flowing RIM, which in the process of dispersion can get into the eyes and breathing of the shooter, thereby causing harm to his health.

The technical task of the proposed utility model is to improve the conditions for safe shooting of the shooter by reducing in the zone of its location the value of the maximum IID of the shock wave generated when the gaseous combustion products of the starting charge flow out from the breech end of the starting device while reducing the mass-dimensional characteristics of the grenade launcher and increasing the muzzle velocity of the grenade.

The technical problem in the proposed utility model is solved by the fact that the design of the disposable grenade launcher contains a launcher closed with sealed covers from the breech and muzzle cuts, sequentially placed in it a grenade, a rocket engine, including a chamber with a launch charge installed in it, and a gas duct, and also a block of inert mass (IM) with a technical liquid in a sealed package, installed in the starting device until it stops in the cut of the gas channel, made in the form of a single-nozzle conical block, and compressed by a compensating ring. The technical liquid in a sealed package is placed in an annular volume formed by an outer cylindrical shell, an inner gas outlet sleeve and annular plugs entering the grooves made at the ends on the outer surface of the gas sleeve, and the inner diameter of the gas outlet sleeve d is (0.2 ... 0 , 6) D, where D is the caliber of the grenade, while the outer cylindrical shell, annular plugs and the inner gas outlet are made of a material easily destroyed by a gas flow, impregnated with a film-forming solution. In this case, longitudinal thinning can be performed on the inner surface of the compensating ring.

The essence of the utility model is illustrated by graphic materials, where Fig. 1 shows a diagram of a grenade launcher, Fig. 2 is a structural diagram of the IM unit; FIG. 3 - connection of the plug with the gas outlet sleeve, FIG. 4, 5, 6, 7 - sequential positions of the grenade and the IM unit during operation, in Fig. 8, 9 - typical graphs of the change in the value of the impulse overpressure over time during the operation of the grenade launcher without the IM unit and with the introduction of the IM unit into the grenade launcher design, respectively.

The grenade launcher consists of a launcher 1, a muzzle cover 2 and breech 3 cuts, a grenade 4 and an IM block 5. A rocket engine 6 is installed on a grenade 4, which has a chamber 7, a starting charge 8 and a single-nozzle conical block 9, behind which is installed in the launcher 1 block
IM 5, pressed against the compensating ring 10. The design of the IM 5 block includes an outer cylindrical shell 11, front and rear plugs 12, connected by a gas outlet sleeve 13, and a sealed package 14, filled with technical fluid 15, located in the internal volume of the IM 5 block.

At the junction points of the plugs 12 near the ends of the gas outlet 13 along the outer diameter, grooves are made in which the plugs are installed 12. The inner surface of the gas outlet 13 is made concentric to the axis of the starting device 1, has a diameter d = (0.2 ... 0.6) D, where D is the caliber of the grenade. Execution of size d in a predetermined range ensures a stable flow of gaseous combustion products of the starting charge through the channel of the gas outlet sleeve 13 into the surrounding space. Execution of d <0.2D is not sufficient for a stable flow of the gas flow into the atmosphere and does not exclude its locking in the starting device 1. Execution of d> 0.6D significantly reduces the volume of technical liquid emitted into the surrounding space to reduce the level of the LED. The exact value of the implementation of dimension d depends on the in-chamber parameters of the rocket engine 6.

To ensure a tight connection of the parts of the IM block, the diameter of the central hole of the plugs 12 is equal to the outer diameter of the grooves made at the ends on the outer surface of the gas outlet sleeve 13, and the outer diameter of the plugs 12 is equal to the inner diameter of the cylindrical shell 11. The shape of the sealed package 14 corresponds to the shape of the inner cavity in the block IM 5.

The compensating ring 10 is made of an elastic material and serves to damp the vibrations of the IM block arising during transportation and transfer of the grenade launcher. On the inner diameter of the compensating ring 10, longitudinal thinning can be made, providing a predetermined destruction into elements with a low level of kinetic energy.

Position 16 designates the volume between the single-nozzle conical block 9 and the IM block 5, which is filled with the combustion products of the starting charge 8 when fired from a grenade launcher. Position 17 denotes an aerosol cloud formed when the technical liquid 15 is sprayed with combustion products.

The following can be used as construction materials:

for the manufacture of shells, plugs and a hollow cylinder - cardboard impregnated with a film-forming solution to protect against the destructive effects of atmospheric factors and corrosive environments;

for the manufacture of flexible packaging - thermoplastic polymers, for example, polyethylene;

as a technical liquid - non-flammable liquid,. retaining its aggregate properties in the temperature range from minus 40 ° С to plus 50 ° С, for example, ОЖ-65, 60% aqueous solution of ethylene glycol (C ₂ H ₆ O ₂ ), 30% aqueous solution of calcium chloride (CaCl ₂ ) _.

The lack of communication between the block of inert mass 5 and grenade 4 reduces the mass of the grenade on the trajectory, thereby increasing its flight range.

The proposed design works as follows. When the starting charge 8 of the engine 6 ignites from the chamber 7, the outflow of gaseous products of its combustion begins through the single-nozzle conical block 9 and the channel of the gas outlet sleeve 13, leading to the undocking of the breech-cut cover 3, the destruction of the compensating ring 10, the movement of the grenade 4 and the IM block 5 along the starting device 1 with the subsequent release of combustion products into the atmosphere. The gas outlet sleeve 13 with an internal channel providing a jet flow of the combustion products of the starting charge 8 excludes the locking of the combustion products of the starting charge 8 in the starting device 1. The movement of the grenade 4 forward leads to the breakdown of the muzzle cover 2 of the starting device 1. When a certain level of pressure in the formed free volume 16 due to the impact of high-temperature gas flow, the outer cylindrical shell 11, plugs 12, gas outlet sleeve 13 of the IM unit of sealed packaging 14 are destroyed, followed by exposure to the technical liquid 15.

In this case, the liquid, when interacting with the environment, is dispersed with the formation of a cloud of liquid-droplet aerosol, the dispersed phase of which consists of micron-sized liquid droplets, in the area of space by the specified cut of the trigger device 1.

The resulting cloud of liquid-droplet aerosol 17 reduces the level of the shock wave formed as a result of the outflow of the combustion products of the starting charge from the nozzle, as well as the temperature of the combustion products due to the interaction of liquid particles with hot gases and, as a result, the field of formation of impulse excess pressures at the location of the arrow changes. As a result, the levels of IRD and the thermal effect of the gas-flame jet on the arrow are reduced.

The presence of a single-nozzle conical block 9, in comparison with the prototype, increases the speed of the gas jet outflow from the engine 6, and, consequently, the engine thrust and the muzzle velocity.

The graph shown in FIG. 8, illustrates the change in the IID values over time at the location of the shooter's head during the operation of the grenade launcher design, which does not have an IM unit in the unit, and in Fig. 9 - the proposed grenade launcher design.

The presented graphs characterize the effectiveness of measures aimed at reducing overpressure levels at the design point. The proposed design of the grenade launcher makes it possible to reduce the maximum level of IID by 60% with a smaller mass of the IM unit compared to the prototype.

The overall weight characteristics of the construction of the IM block are determined for the given parameters of the grenade launcher and the range of a direct shot by calculation and are refined according to the test results, subject to the safety requirements of the shooter.

The technical result of the utility model is to reduce the value of the maximum ID, the risk of thermal effects of a gas-flame jet on the shooter under conditions of firing from semi-closed positions and rooms, and also to reduce the passive mass of the grenade on the trajectory and the total mass of the grenade launcher with an increase in the muzzle velocity of the grenade.

Claims (2)

1. A disposable grenade launcher, containing a launcher closed with sealed covers from the breech and muzzle cuts, sequentially placed in it a grenade, a rocket engine including a chamber with a launch charge and a gas-water channel installed in it, as well as a block of inert mass with a technical liquid, which is different by the fact that the block of inert mass is installed in the starting device until it stops in the cut of the gas channel, made in the form of a single-nozzle conical block, and is compressed by the compensating ring, and the technical liquid in a sealed package is placed in the annular volume of the block of inert mass formed by the outer cylindrical shell, the inner gas outlet bushing and annular plugs entering the grooves made at the ends on the outer surface of the gas outlet sleeve, and the inner diameter of the gas outlet sleeve d is equal to (0.2 ... 0.6) D, where D is the caliber of the grenade, with the outer cylindrical shell, ring plugs and internal vent bushing They are made of a material that is easily destroyed by a high-temperature gas flow and is impregnated with a film-forming solution. 2. A disposable grenade launcher according to claim 1, characterized in that longitudinal thinning is made on the inner surface of the compensating ring.

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