RU2071583C1 - Mover of recoilless gun - Google Patents

Abstract

FIELD: military equipment. SUBSTANCE: mover includes combustion chamber with front and rear nozzle units in which nozzles are arranged on periphery, front and rear nozzle grates, nozzle charge placed between them, igniter, electric primer, hollow spherical cap os additionally placed between rear nozzle grate and rear nozzle unit. It includes throttle holes oriented towards powder charge, blind recesses being formed between them. Casing made from ductile metal with igniter in the form of pyrotechnical tracker of burning of powder charge positioned around branch pipe with electric primer is placed equidistantly to internal surface of cap. Ring with radial groove oriented towards casing with igniter is positioned on rear nozzle unit under cap. Rear nozzle grate is attached to cap and is manufactured in the form of perforated disc with arc slots and radial partitions between them. Ring reflector is fixed uniaxially on front nozzle grate on side of front nozzle. Inlet sections of front nozzle protrude into combustion chamber. EFFECT: increased operational reliability. 4 dwg

Description

 The invention relates to military equipment and can be used in the development of propulsion systems recoilless guns.

 A recoilless gun is known [1] in which a perforated sleeve with a powder charge and an igniter is used as a propulsion system. In this design, the side surface of the liner has a large number of small holes providing for the combustion of the powder charge in the liner. An annular chamber is formed in the barrel along the periphery of the side walls of the liner, into which powder gases from the liner flow. A shell is rolled in a sleeve. Failure is ensured by the reactive power of the expiring powder gases through nozzles in the bottom of the chamber.

 However, the described design of the recoilless gun propulsion system does not provide stable dynamic balance of the gun (container) allowed for firing directly from the shooter's hands.

 To some extent, this drawback was eliminated in the design of the recoilless gun propulsion system [2] taken as a prototype and made in the form of an insert combustion chamber with front and rear nozzle blocks. The powder charge is located between the front and rear nozzle grilles. The ignition of the charge is carried out by an igniter hitch and an electric igniter. To mount the propulsion system in the barrel, radial pylons are fixed on the side walls of the combustion chamber. The projectile is pushed out of the barrel by the pressure of the powder gases flowing out through the front nozzle block, and the recoil force is compensated by the reactive force arising from the flow of the powder gases through the rear nozzle block and through the gap between the barrel and the side wall of the combustion chamber.

The main drawback of the design is the unstable ignition of the powder charge along its length, which, during short-term operation during the movement of the projectile along the barrel, leads to significant emissions of unburned particles. If they are ejected through the front nozzle block with the projectile space, they die out in the barrel at a lower pressure than in the propulsion system, reducing the total impulse of the powder charge. Unburned particles of gunpowder thrown out through the rear nozzle block burn out already outside the barrel, also reducing the total impulse of the powder charge. And since the operation of recoilless guns is carried out in a wide temperature range, usually from plus 50 ^o С to minus 50 ^o С, then the emission of particles will be different, which leads to a large dispersion of the momentum of dynamic imbalance of the recoilless gun, exceeding the allowable for firing in direct contact a person with a gun without complex shock absorbing devices.

 The problem to which the invention is directed, is to increase the dynamic balance of recoilless guns in the range of operating temperatures.

 This object is achieved by the fact that in a propulsion system of a recoilless gun containing a combustion chamber with front and rear nozzle blocks, with nozzles peripherally located in them, front and rear nozzle grilles, between which there is a nozzle charge, an igniter, an electric igniter in it additionally between the rear nozzle a hollow spherical cap with throttle openings oriented towards the powder charge, between which a blind recess is formed, is installed by the grill and the rear nozzle block and, and in the cap, equidistant to its inner surface, a plastic metal case with an igniter is installed in the form of a pyrotechnic escort of the powder charge combustion, which is placed around the nozzle with an electric igniter, and a ring with a radial groove oriented towards the ignition case is installed on the rear nozzle block under the cap moreover, the rear nozzle grill is bonded to the cap and made in the form of a perforated disk with arc slots and radial bridges between them, and on the front an annular reflector is coaxially fixed to the nozzle array from the front of the front nozzles, while the entrance portions of the front nozzles protrude into the combustion chamber.

 Figure 1 shows a General view of the propulsion system, section; figure 2 - a view of figure 1; figure 3 section BB in figure 1; figure 4 ring with a radial groove.

 The propulsion system comprises a combustion chamber 1 with a front nozzle block 2 with nozzles 3 deepened into the chamber to form pockets, and a rear nozzle block 4 with nozzle holes 5. The front and rear nozzles are sealed with destructible front 6 and rear 7 membranes. The powder charge 8, made in the form of a tube bundle, is placed between the front 9 and rear 10 gratings. A cap 11 with throttle openings 12 is installed on the rear nozzle block, between which blind recesses 13 are made. A pyrotechnic combustion guide 14 is placed in the cap in a spherical case 15 made of plastic metal around a pipe 16 with an electric igniter 17. A ring 18 with a radial groove is installed under the cap. The rear nozzle grill is fastened to the cap with screws 19 and is made in the form of a perforated disk with arc slots 20 and radial bridges 21 between them. An annular reflector 22 is fixed on the front grill opposite the front nozzles. On the side walls of the combustion chambers there are pylons 23 joined to the barrel wall.

 Installation works as follows.

 When an electric current is supplied to the electric igniter 17, a force of flame is formed, which ignites the pyrotechnic combustion conductor 14. In this case, the force of the flame of the electric igniter located in the cylindrical pipe 16 falls on the spherical inner surface of the cap and "spreads" along it, completely covering the surface of the pyrotechnic combustion conductor 14 , which ensures uniformity of the ignition conditions of the latter.

 High-pressure gases from the combustion of the escort through the throttle openings 12 fill the combustion chamber 1, while the radial jumpers 21 and the arc slots 20 play the role of a gas-dynamic screen, providing crushing of high-pressure jets of gas in front of the powder charge 8 to prevent its destruction. When the calculated pressure is reached in the combustion chamber, the front 6 and rear 7 membranes, sealing nozzles, break through. A reflector 22 mounted opposite the front nozzles causes unburned powder particles to move past the nozzle openings toward the spherical bottom. At the same time, the walls of the nozzles 3 recessed into the combustion chamber ensure the gas flow is twisted, extending its path to the exit through the nozzles, which in turn improves the completeness of combustion of solid powder particles inside the combustion chamber. Powder gases flowing out through the rear nozzles 5, on their way in the pre-nozzle cavity are exposed to jets of gas flowing from the throttle holes 12 of the cap 11. In this case, they are intensively mixed, which increases the completeness of combustion of solid unburned particles of gunpowder.

 When the igniter is activated, the case 15 is squeezed out by internal pressure along the inner spherical surface of the cap 11 and around the nozzle, filling the blind recesses 13 and the groove of the radial ring 18. This ensures that the case is not pulled out through the throttle openings of the cap and their overlapping by the material of the case during combustion of the combustion guide. And this, in turn, allows to reduce the overturning moment of the gun when firing, thereby increasing firing accuracy.

Claims (1)

 A recoilless gun engine installation comprising a combustion chamber with front and rear nozzle blocks, nozzles peripherally located therein, front and rear nozzle grills, between which there is a nozzle charge, an igniter, an electric igniter, characterized in that it additionally between the rear nozzle grill and the rear the nozzle block has a hollow spherical cap with throttle openings oriented towards the powder charge, between which blind recesses are formed, and in the cap equidis the antenna of its inner surface is fitted with a plastic metal case with an igniter in the form of a pyrotechnic escort for burning a powder charge, which is placed around the nozzle with an electric igniter, and a ring with a radial groove oriented toward the case with an igniter is installed on the rear nozzle block, with the rear nozzle grill fastened with a cap and made in the form of a perforated disk with arc slots and radial bridges between them, and on the front nozzle grill with Oron front annular nozzles coaxially fixed reflector, the input portions of the front nozzles protrude into the combustion chamber.

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