RU2107886C1 - Cartridge with active-reactive bullet (variants) - Google Patents

Abstract

FIELD: smoothbore small arms of normal caliber. SUBSTANCE: cartridge has a case with propelling charge and active-reactive bullet. The bullet has a head using an envelope with an obturator, lead jacket and a slug, and a jet engine. The engine has a case with nozzles, powder cylinder and a cover. The nozzles are positioned radially in the front part of the case. A turbine is installed on the external surface of the engine case rear part. The cartridge of the first variant of the case is cylinder-shaped, and that of the second variant is bottle-shaped. The jet engine of the cartridge of the second variant is furnished with a centering rod passing through the central nozzle, made in the rear part of the case. EFFECT: enhanced efficiency. 2 cl, 6 dwg

Description

 The invention relates to ammunition for a smooth-bore small-caliber weapon of normal caliber.

 The closest analogue of the invention is an cartridge with an active-reactive bullet, designed for smooth-bore weapons of normal caliber, containing a sleeve, propelling charge, an igniter capsule, an active-reactive bullet consisting of a shell with a core, a jet engine, including a body with nozzles, a powder cylinder and stub.

 The essence of the invention is the creation of a cartridge for a smooth-bore small-caliber weapon of normal caliber, with a small recoil momentum, a relatively high initial velocity of the bullet and the possibility of further increasing the speed of the bullet after departure from the bore with giving it stable stabilization in the barrel and on the flight path.

 To solve this problem, an automatic cartridge with an active-reactive bullet, with a cylindrical sleeve with a light taper, as well as an automatic cartridge with an active-reactive bullet, with a bottle-shaped sleeve, are presented.

 In FIG. 1 shows a General section of the automatic active-reactive cartridge with a sleeve of cylindrical shape, a static state; in FIG. 2 - the same, with a bottle-shaped sleeve, a static state; in FIG. 3 is a section AA in FIG. 2; in FIG. 4 is a section BB in FIG. 2; in FIG. 5 - automatic active-reactive bullet for a sleeve of cylindrical shape, axonometry; in FIG. 6 - the same for a bottle-shaped sleeve, axonometry.

 An active-reactive cartridge is a non-separable assembly unit consisting of a cartridge case with a propelling charge and an active-reactive bullet.

 The sleeve 14 of an automatic cartridge of a cylindrical shape (Fig. 1) with an igniter 25 is designed to place a propellant charge 19, an active-reactive bullet 26 and hold it in the assembled state, as well as to create an obturation between the sleeve and the chamber of the weapon, for directing the initial translational and rotational movement of the active-reactive bullet 26 until it fully enters the barrel channel and is the combustion chamber of the propellant charge 19. The sleeve 14 is a thin-walled metal glass with a light outer cone awn from ignition fuse 25 and an annular groove 24 for ekstraktirovaniya purposes.

 The sleeve 14 of the automatic bottle-shaped cartridge (Fig. 2) differs from that described by the presence of a conical ramp 13 and a dulcie 7, approximately equal in diameter to the barrel bore (equal at the time of the shot), a centering metal rod 16 pressed into the anvil body 23 of the sleeve 14 and designed to direct the initial translational and rotational motion of the active-reactive bullet 26, until it comes out of the sleeve.

 The propellant charge 19 is intended to give the active-reactive pool 26 an active initial rotational speed and is smokeless pyroxylin powder.

 Active-reactive bullet 26 (Fig. 1) is designed to defeat manpower and unarmored vehicles and is a non-separable assembly unit consisting of a head part 1 and a jet engine 15. The head part 1 is an ordinary shell bullet consisting of a lead shell 2 shirt 3 and a steel core 4, pressed onto the front of the jet engine housing 15 and compressed along the annular groove 9 between the thickenings of the housing. The skirt 12 of the shell 2 is a shutter representing a breakthrough of powder gases between the bullet and the barrel of the weapon. The jet engine 15 is designed to create jet thrust from the moment of ignition of the powder checkers 18 in the bore and on the flight path, as well as torque through the turbine 21 during the movement of the bullet 26 along the bore. The jet engine 15 consists of a housing 15, a powder cylinder (checkers) 18 and a plug 5. The housing of the jet engine 15 serves to connect all parts of the active-reactive bullet 26, together with the plug 5 is a combustion chamber of a cylindrical checker 18 and consists of a steel thin-walled glass, outside - behind which there is a turbine 21 with oblique-bladed blades 20, in the front - radially located supersonic slotted nozzles 11. The inner cylindrical surface of the larger case is used to install a 5 sec plug its subsequent rolling.

 The powder cylinder 18 is a mixed powder checker having in the upper part longitudinal grooves 8 for the passage of powder gases and an armored casing outside below the grooves. When ignited, the checker initially has a degressive burning rate, and below the level of the grooves it has a constant. The powder charge 18 in the assembly process is pressed into the engine housing.

 The plug 5 is designed to seal the engine from above. It is a profiled circle with beads at the edges for rolling purposes.

 The device of the active-reactive bullet 26 for an automatic cartridge with a bottle-shaped sleeve (Fig. 2) is similar to that described (Fig. 1), except that in the housing of the jet engine 15 in the lower part there is an axial subsonic nozzle 22, which serves to pass through it centering the sleeve rod 16, as well as the creation of traction from the moment of ignition of the powder tube checker 17. The powder checker 17 has the shape of a tube with an axial hole equal to the diameter of the centering rod 16 in the upper part of the groove 8 for the passage of powder gases. The checker is armored below the grooves.

 When the propellant charge 19 (Fig. 1) is ignited from the igniter capsule 25, the gases formed, having a high temperature and pressure, carry out a buoyant action on the active-reactive bullet 26 in the direction of the muzzle of the barrel. At the same time, part of the propellant propellant gas gases located in the cavity between the engine body 1, the walls of the liner 14, the radial nozzles 11 and the turbine 21 tend to go towards the turbine, forcing the latter to rotate the bullet due to the blades 20 rolled onto the body. Bullet 26, making translational and rotational movements, leaves the cavity of the sleeve into the barrel, gaining speed and rotation. Simultaneously, from the breakthrough of part of the powder gases through the nozzle holes 11, the powder bomb 18 of the jet engine will ignite. The resulting powder gases flowing out of the radial nozzles 11 will create additional speed and rotation of the pool in the active area. After the departure of the active-reactive bullet 26 from the bore, the jet engine continues to operate, creating an increase in flight speed until the powder burst 18 burns out. The rotation of the active-reactive bullet 26 on the flight path is supported by the high-pressure head of oncoming air acting on the inclined blades 20 of the turbine 21 which simultaneously fulfill the role of an air stabilizer.

 When the propellant charge 19 (Fig. 2) is ignited from the igniter capsule 25, the gases formed push out the active-reactive bullet 26, which, translating in the direction of the muzzle of the barrel, is centered around the axis of the sleeve by a centering rod 16, which, as it moves the bullet 26 leaves the internal cavity of the jet engine 15 through the axial nozzle 22 until the active-reactive bullet 26 completely leaves the liner 14. At the same time, a portion of the powder gases of the propellant charge 19 of the nozzle holes 11 ignites gunpowder tubular checker 17 of the jet engine. Active rotational movement of the bullet 26 will receive at the moment of entering the turbine 21 in the neck 13 of the sleeve 14 due to the gases flowing out of the radial nozzles 11, the impact on the helical blades 20 of the turbine, and will continue until the bullet 26 leaves the barrel. The speed of the bullet in the barrel will increase from the effects of the propellant gases of the propellant charge 19 and the jet engine 15. After the departure of the active-reactive bullet 26 from the barrel, its movement will be similar to that described (Fig. 1, 6).

Claims (2)

 1. An automatic rifle cartridge with an active-reactive bullet, designed for a smooth-bore small-caliber weapon of normal caliber, containing a sleeve, a propelling charge, an igniter capsule and an active-reactive bullet, consisting of a head part in the form of a shell with a core and a jet engine including a body with nozzles , a powder cylinder and a plug, characterized in that the jet engine nozzles are located radially in front of its housing, and on the outer surface of the rear of the jet engine housing a turbine, while the bullet head is provided with a jacket, the shell of the bullet is made with an obturator, and the sleeve has a cylindrical shape.  2. A submachine gun with an active-reactive bullet, designed for a smooth-bore small-caliber weapon of normal caliber, containing a sleeve, a propelling charge, an igniter capsule and an active-reactive bullet, consisting of a head part in the form of a shell with a core and a jet engine including a body with nozzles , a powder cylinder and a plug, characterized in that the jet engine nozzles are located radially in front of its housing, and a turbine is installed on the outer surface of the jet engine housing, This jet is provided with a centering rod extending through the central nozzle, formed in the rear portion of its body, the head portion is provided with a jacketed bullet, the bullet casing is formed with the obturator and the sleeve has a bottled form.

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