RU2196288C2 - Method for removal of powder gases from bore after shooting of artillery gun and device for its realization - Google Patents

Abstract

FIELD: military equipment, applicable in self-propelled artillery guns, tanks, infantry fighting vehicles and ship artillery mounts. SUBSTANCE: the method consists in the fact that ejection is produced after extraction of the shell case by applying an air impulse with a duration of 0.3 to 0.8 s to the cavity of the diffuser of the mechanism for removal of powder gases. The mixture of powder gas with air is discharged from the fighting vehicle together with the shell case. The mechanism for removal of powder gases from the gun bore is made in the form of nozzles feeding the air impulse to the diffuser cavity. The diffuser is installed behind the gun breech and provides for direction of gas flow from the breech to the fighting vehicle hatch for extraction of the gun case. The nozzles are inclined at an angle of 15 to 20 deg to the bore axis towards the shell case extraction. EFFECT: reduced gassing of the fighting compartment at gun shooting and expanded field of application of the barrel blow-through ejection system. 2 cl, 2 dwg

Description

 The invention relates to military equipment and can be used in self-propelled artillery installations, tanks, infantry fighting vehicles and naval artillery installations.

 There is a method of removing powder gases from the barrel of an artillery gun when firing shotgun shells (1). The method is carried out by supplying compressed gas to the bottom of the sleeve from a source of compressed gas located in the sleeve. The feed occurs between the moment the projectile leaves the barrel and the moment the shell completely leaves the breech in the process of extraction.

 The disadvantage of this method is an increase in the weight of the shot due to the introduction of additional devices and a decrease in the powder charge of the sleeve.

A known method and device for blowing the bore of the gun barrel of a T-62 tank (2), selected for the prototype. The method includes the following operations:
- after firing, part of the powder gases is directed from the bore to the blowing mechanism (ejector) located on the gun’s barrel;
- remove powder gases from the bore through the muzzle opening due to ejection. Gunpowder gases exit the nozzle openings of the purge mechanism and carry gunpowder gases from the bore;
- extract the sleeve after the ejection process.

 The method is implemented in an ejector-type blowdown mechanism located on the gun barrel. The blowing mechanism is used to remove powder gases from the bore after firing and to reduce the gas contamination of the fighting compartment of the tank. The blowing mechanism consists of a receiver, worn on the barrel and tightened with a nut until it stops in the shoulder.

 The internal cavity of the receiver communicates with the bore by six inclined holes with nozzles. The nozzles are screwed into the threaded holes of the barrel. The blowing mechanism operates as follows. When firing after passing through the nozzle holes with the obturation belt of the projectile, part of the powder gases through these holes fills the cavity of the receiver. The flow of gases from the barrel to the receiver cavity occurs until the pressure is equalized in the barrel and in the receiver. Starting from the moment the projectile leaves the bore, the pressure in it drops sharply. Gases from the receiver cavity under pressure created there at the initial moment begin to flow out through the nozzle openings in the direction of the muzzle of the barrel due to the inclination of the openings, while the gases present in the barrel channel are sucked out.

The disadvantages of this method and device for its implementation are:
- incomplete blowing of the bore as the nozzle hole of the receiver becomes contaminated with unburned powder particles;
- low efficiency of the blowing mechanism on artillery guns with low ballistics (low pressure of powder gases in the bore).

 The objective of the invention is to reduce the gas contamination of the fighting compartment when firing an artillery gun and expand the scope of the ejection system for blowing through the barrel.

 The problem is solved in that in the method of removing powder gases from the barrel channel after firing an artillery gun mounted in a combat vehicle, including the removal of the gas stream into the mechanism for removing powder gases, the removal of powder gases from the barrel channel due to ejection and sleeve extraction, ejection is created after sleeve extraction by applying an air pulse of 0.3 ÷ 0.8 s duration into the cavity of the diffuser of the powder gas removal mechanism. A mixture of powder gas with air is diverted outside the combat vehicle along with a sleeve.

 The method is implemented by the fact that in a gun installation containing an artillery gun mounted in a combat vehicle and a mechanism for removing powder gases from the barrel channel after a shot, the mechanism for removing powder gases from the channel of the gun barrel is made in the form of nozzles supplying an air pulse to the diffuser cavity. The diffuser is installed behind the breech of the gun and provides the direction of the gas flow from the breech of the barrel into the hatch of the ejection sleeve of the combat vehicle.

The nozzles are inclined at an angle of 15 ÷ 20 ^o to the axis of the bore in the direction of the sleeve.

 In FIG. 1 shows a mechanism for removing powder gases from a bore after a shot, side view; figure 2 is a section along the axis of one of the nozzles.

The gun installation that implements the method consists of an artillery gun 1 (Fig. 1) installed in a combat vehicle 2. A diffuser 3 is installed behind the breech of the gun, directed into the opening "α" of the ejection sleeve 5 of the combat vehicle 2. Side of the breech of the gun 1, inside the diffuser 3, at a distance of 150 ÷ 250 mm from the breech section of the bore, nozzles 6 are installed, which are connected by a pipeline 7 to the gearbox and a cylinder of compressed air. The nozzles 6 are inclined at an angle α to the wall of the diffuser 3 (figure 2) and are directed towards the departure of the sleeve. Angle α = 15 ÷ 20 ^o .

 Gun installation works as follows. After the shot, the moving parts of the gun 1 are rolled back and mounted on the sear. In this case, the shutter 4 is in the upper position, and the sleeve is in the chamber of the bore. To eject a fired cartridge case, gun 1 is set to the firing angle of the cartridge case, hatch 5 is opened. When the “extraction” button on the remote control of the combat vehicle is pressed, the moving parts of the gun 1 are reset from the sear, the shutter 4 is lowered and the fired cartridge case is extracted into the ejection hatch 5 outside the combat cars. Simultaneously with the discharge of the movable parts of the gun 1 from the sear, the electro-pneumatic valve of the air system is activated and compressed air flows through the nozzle 6 through the nozzles 6 into the cavity of the diffuser 3. Air is supplied for 0.30 ÷ 8 s. Powder gas located in the bore and moving after the sleeve, under the influence of air flow rushes into the hatch ejection sleeve.

 Thus, the proposed method and device for its implementation can reduce the gas contamination inside the combat vehicle when firing an artillery gun and expand the scope of the ejection system for blowing the bore.

Sources of information
1. Patent 1745148 from 04/05/91, SU, cl. F 42 V 5/00, F 41 A 13/06 - analogue.

 2. 125-mm tank guns 2A26 (D-81) and 2A26M2. Technical description and operating instructions, parts 1,2,3,4. Military publishing house of the Ministry of Defense of the USSR. - M .: 1974, pp. 12-13 - prototype.

Claims (2)

 1. A method of removing powder gases from a barrel channel after firing an artillery gun mounted in a combat vehicle, comprising discharging a gas stream into a mechanism for removing powder gases, removing powder gases from a barrel channel by ejection, extracting a sleeve, characterized in that the ejection is created after extraction sleeves by supplying an air pulse of 0.3-0.8 s duration to the cavity of the diffuser of the powder gas removal mechanism, while the mixture of powder gas and air is diverted outside the fighting vehicle together with the shells Oh. 2. A gun installation containing an artillery gun mounted in a combat vehicle and a mechanism for removing powder gases from the barrel channel after a shot, characterized in that the mechanism for removing powder gases from the channel of the gun barrel is made in the form of nozzles supplying an air pulse to the cavity of the diffuser installed behind the breech of the gun with the direction of the gas flow from the breech of the barrel into the hatch of the ejection sleeve of the combat vehicle, while the nozzles are inclined at an angle of 15-20 ^o to the axis of the barrel bore towards the departure of the sleeve .

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