RU2584405C1 - Method of shooting from cannon unitary shot and fixed round therefor - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: invention relates to ammunition, namely, to quick-firing rounds and methods of firing with them. Quick-firing round comprises a shell with a shank, a cartridge with a percussion primer, igniter and propellant charge, a chamber and a pusher. Chamber is located in the central channel and is attached to the shell bottom. Located in the shank of the shell there is an initiator of the igniter with a launch device. Pusher is made in the form of a piston with ring seals contacting with the chamber inner surface. In axial direction, the piston contacts with shell shank. In the chamber, on the side facing the shell shank, there is a installed a piston trap with a holder. Igniter initiator launch device is made in the form of an inertial load. Method of shooting from a cannon by quick-firing rounds includes actuation of a percussion primer, initiation of the igniter and propellant charge, displacement of the shell, biting into the shell and reduction of its obturating band in the artillery tube and further projection of the shell from a tube. Initiation of the igniter and propellant charge is performed after displacement of the shell and biting into its obturating band in the tube. Shell displacement and biting into its obturating band is ensured by action of powder gases.

EFFECT: higher efficiency of fire.

4 cl, 3 dwg

Description

The proposed group of inventions relates to the field of artillery weapons, and specifically to methods of firing artillery with unitary shots and the design of unitary shots (unitary loading shots).

Known ammunition (artillery shot of unitary loading) and the method of its manufacture (US Patent No. 4 803927, MKI ⁵ F42B 5/02, publication date 02/14/1989).

Known ammunition (shot) contains a shell, a sleeve with a capsule and a main propelling charge, in which a central channel is formed to accommodate the shell. The munition also contains a pipe with a closed first end that is attached to the sleeve and an open second end. The pipe passes to the tail end of the projectile inside the central channel. An annular groove is made on the outer surface of the pipe. The projectile also has an annular recess extending from its tail end. The second end of the pipe enters the recess. The pipe has a thin-walled device for its connection with the projectile when combining both annular grooves and placing this device in them. A device is installed in the pipe for generating gases that cause the projectile to move from the pipe inside the channel and ignite the main propellant charge.

When the above shot is functioning, a method of firing a gun is implemented, which includes firing the capsule sleeve, initiating the igniter and the main propellant charge, moving the projectile, biting and squeezing the obturating belt of the projectile in the barrel, and the subsequent projectile firing from the barrel.

The design of this shot allows to reduce its longitudinal size and increase the velocity of the projectile by placing the main propellant charge of increased mass along the entire length of the shell and around the projectile.

The disadvantage of this design of the shot is that the described shot has large transverse dimensions (propellant charge is located around the projectile) and can be used with guns having a large bottle loading chamber, and is not applicable for guns in which the diameters of the shell and shell are comparable.

A unitary loading shot is also known (RF Patent No. 2038569, application No. 5028146 dated 02.21.1992, IPC F42B 5/02 - prototype) containing a sleeve with a capsule and a propelling charge, a perforated chamber and a projectile. In it, the projectile is equipped with a shank, in which an electric igniter equipped with a retardant pyroside composition is placed, and a power source is installed in the bottom of the projectile, electrically connected to the electric igniter and the electronic components of the projectile, the shank being located in the chamber barrel and a flexible element fixed to its end, on the outer surface of the shank in the area adjacent to the flexible element, an annular ledge is made, around which the perforation of the chamber is located, and in the chamber there is an annular protrusion on which p a separating membrane of combustible material, and an igniter is located between the membrane and the electric igniter. An electric igniter with a retarding composition, which initiates an igniter and then a propellant charge through a time delay, is connected to a power source (inductor), which induces EMF from interaction with a pusher (striker) when the capsule sleeve is triggered. The time delay provided by the decelerating pyrocomposition of the electric igniter is necessary for starting electronic components and projectile elements.

During the operation of this shot, a unitary firing method is implemented, including firing the capsule sleeve, initiating an igniter and propellant charge through a time delay, moving the projectile, biting and squeezing the obturation belt in the barrel, and the subsequent projectile departure from the barrel.

The above-mentioned shot and method of firing allow firing of guided projectile guns through the time delay necessary to engage the components and components of the on-board equipment of the guided projectile. In addition, this design of the shot improves the stability of ballistic characteristics.

However, guided projectiles, compared with unguided ones, have large longitudinal dimensions (large length) due to the presence of additional compartments (compartments of the control system, main engine, etc.). In order to ensure the placement of unitary shots with guided projectiles in standard ammunition and automatic loaders, it is necessary that their longitudinal dimensions correspond to the longitudinal dimensions of regular shots with unguided shells. To fulfill this condition, it is necessary to shorten the sleeve. Taking into account that the obturating belt on the projectile is located, as a rule, in the area of the shell barrel, then the distance between the obturating belt and the insertion cone (support cone) of the standard gun’s barrel, in which the belt is bitten and crimped, increases. As a result of this, when a propellant is triggered, its combustion products, having a speed much higher than the velocity of the projectile at the beginning of its movement, rush along the annular gap between the barrel chamber and the projectile and overtake the projectile by acting on its side surface with its pressure. The pressure of the combustion products acting on the side surface of the projectile can reach significant values, which leads to the need for hardening the projectile nodes and complicates the sealing of joints between nodes (gas breakthrough at the joints can lead to failure of the components and elements of the projectile, i.e. reliability). This continues until the obturation band bites and squeezes in the trunk. Thus, a significant part of the propellant combustion products does not provide work to accelerate the projectile, i.e. the energy of combustion products is used with low efficiency. Therefore, to inform the projectile of the required muzzle velocity, it will be necessary to increase the mass of the propellant charge, which will lead to an increase in pressure in the sleeve and thereby increase the load on the projectile and gun.

In addition, under the influence of the products of combustion of the igniter and the propellant charge, with an increased distance between the obturating belt and the cone of cutting the barrel, the shell manages to gain a relatively high speed by the time the belt is bitten. The process of biting and crimping the belt, which occurs at a relatively high velocity of the projectile acquired under the action of the products of ignition of the igniter and the products of combustion of the propellant charge during its ignition, is accompanied by rather significant dynamic loads (shock overload braking), which negatively affects the strength and functioning of the nodes and elements shells, especially electronic, optical and precision mechanics, and can lead to their failure.

The problem to which the invention is directed, is to increase the efficiency of using the energy of the products of combustion of the igniter and propellant, as well as improving the reliability of the nodes and elements of the projectile of a unitary shot.

The solution to this problem is achieved by the fact that in the known method of firing a cannon with a unitary shot, including the operation of the capsule sleeve, initiating the igniter and propellant charge through a time delay, moving the projectile, biting and squeezing its obturating belt in the barrel and the subsequent departure of the projectile from the barrel, initiating the igniter and a propellant charge is carried out after moving the projectile and biting its obturating belt in the barrel, while moving the projectile and biting its obturations the radiating belt provide the work of powder gases isolated from the igniter and propellant charge.

The implementation of the method of firing a gun is carried out by the operation of a unitary shot containing a shell with an obturating belt and a shank with an annular groove, a sleeve with a capsular sleeve, an igniter and a propelling charge, in which a central channel is formed, a camera located in the central channel, fastened to the bottom of the sleeve and in which contains the shank of the projectile, the pusher interacting with the shank of the projectile when the capsule sleeve is triggered, while the initiator ignites in the shank of the projectile For a launching unit, it is triggered through a time delay relative to the operation of the capsule sleeve, in which the pusher is made in the form of a piston with ring seals in contact with the inner surface of the chamber, while in the axial direction the piston contacts the shank of the projectile, and in the chamber, from the side facing the shank of the projectile, a piston trap with a clamp is installed, the igniter is made in the form of a toroidal cap with a powder composition placed in it, covering the shank of the projectile along the front hole, the igniter initiator launch unit is made in the form of an inertial load, telescopically mounted in the cavity of the projectile shank, fixed from longitudinal movement relative to the projectile shank by an element that is destroyed when biting and crimping the obturation belt in the gun barrel, and activating the igniter initiator, or an electric power source connected with igniter initiator. The igniter initiator can be made in the form of an electric igniter connected to a power source, which is activated by an inertial load. The initiator of the igniter can also be made in the form of a capsule sleeve, while the inertial load is equipped with a protrusion-tip, located opposite the capsule sleeve. And in addition, the initiator of the igniter can be made in the form of a capsule sleeve placed on the end of the inertial load facing the bottom of the projectile, while in the shank of the projectile opposite the capsule sleeve there is a protrusion-cap

The invention is illustrated in graphic materials.

In FIG. 1 schematically shows the construction of a unitary shot made in accordance with paragraph 4 of the claims.

In FIG. 2 schematically shows the design of the igniter initiator and its launch unit, made in accordance with paragraph 3 of the claims.

In FIG. 3 schematically shows the design of the igniter initiator in the form of an electric igniter connected to a power source activated by an inertial load.

A unitary loading shot contains a projectile 1 with an obturating, for example, copper belt 2 and a shank 3 with an annular groove 4, a sleeve 5 with a capsule sleeve 6, an igniter 7 and a propelling charge 8. A central channel 9 is formed in the propelling charge 8, in which the chamber 10 is located fastened to the bottom 11 of the sleeve 5 by means of a threaded adapter 12. A shank 3 and a pusher made in the form of a stepped piston 13 with O-rings 14 are placed in the chamber 10. The piston (pusher) 13 contacts axially with the shank 3. In the chamber 10, from the side facing the shank 3 of the projectile 1, a piston trap 13 is installed, made, for example, in the form of a threaded sleeve 15 with a conical brake section 16. A conical bevel 17 is made on the larger diameter of the stepped piston 13, which provides entry and smooth braking on section 16. In the threaded sleeve 15 is placed a piston retainer 13, made, for example, in the form of a spring split ring 18 installed in the annular groove of the threaded sleeve 15 and latched into the annular groove 19 after they are aligned when the piston 13 is advanced. the igniter 7, made in the form of a toroidal cap with a powder composition placed therein, covers the shank 3 along the annular groove 4. The igniter initiator can be made in the form of a capsule sleeve 20 or an electric igniter 21, while its launch unit is made in the form of an inertial load 22, telescopically installed in the cavity of the shank 3, fixed by a destructible, for example shear (shear) element (s) 23, the destruction of which (which) occurs by inertial forces during preliminary compression and biting the obturation belt 2 in the gun barrel 24. Destructible, for example shear, element 23 is calculated and worked out experimentally in such a way as to withstand various operational loads provided by the technical documentation (loads during transportation, falls, etc.), and be destroyed by inertial forces during braking when biting the obturating belt 2. Mass the inertial load 22 is selected so that due to the inertial forces acting on the projectile 1 and its elements when braking from biting the belt 2 in the barrel, destruction occurs (cut f) of the element 23 and then the load 22 would have kinetic energy sufficient for the capsule sleeve 20 or the power supply 26 to operate. The inertial load 22 after the shear element 23 is broken inertia and activates the capsule sleeve 20 using the protrusion-tip 25 or activates the source power supply 26, connected to the electric igniter 21. The configuration of the protrusion-kneecap 25 is performed similar to the configuration of the striker trigger mechanisms of weapons, which use the same capsule sleeve. The power source 26 can be made in the form of a chemical battery activated by an inertial load 22, or an inductor generating EMF upon impact with an inertial load. The gas-dynamic connection of the products of combustion of the capsule sleeve 20 or the electric igniter 21 with the igniter 7 is through holes 27 made in the shank 3 and the inertial load 22 (if necessary, and constructive performance of the inertial load in accordance with Fig. 1). If there is a lack of energy of the combustion products from the actuation of the capsule sleeve 6 to reliably overcome the efforts of flaring the projectile 1 in the sleeve 5, pre-bite and crimp the obturating belt 2 in the conical bevel 31 of the barrel 24, an additional powder hinge 28 can be used. Reliable biting of the obturating belt 2 in the conical bevel 31 involves fixing and holding the projectile 1 on its belt in the barrel, including at the maximum possible elevation angle of the gun barrel. If necessary, to enhance the thermogasdynamic effect on the igniter 7, an additional powder hinge plate 29 can be used. Holes 30 are used to exclude compression in the cavity of the liner 3 when the inertial load 22 is moved along it. The barrel 24 has a tapered bevel 31 of grooves in which biting and crimping takes place obturation belt 2.

The implementation of the method of firing a weapon with a unitary shot will be shown by the example of the functioning of a unitary shot.

When the trigger mechanism of the guns of its firing pin is triggered (not shown on graphic materials), it initiates a capsule sleeve 6, the combustion products of which, reinforced if necessary by the combustion products of the powder suspension 28, act on the piston 13. The pressure from the combustion products of the capsule sleeve 6, acting on the end face of the piston 13, through the shank 3 is transmitted to the projectile 1 and after overcoming the flaring effort, the projectile 1 begins to move relative to the sleeve 5 and the barrel 24. The piston 13 moves relative to the chamber 10, Single projectile 1 which, gaining speed, flows into the barrel 24 guns. In this case, the O-rings 14 exclude the breakdown of the combustion products of the capsule sleeve 6 from the cavity of the chamber 10. As the piston 13 moves along the chamber 10, its part, having a larger diameter with a bevel 17, enters the conical brake section 16 of the sleeve 15, where smooth braking and trapping occurs piston. In this case, the piston 13 is stuck in the conical brake section 16 and is additionally fixed by a spring split ring 18, which snaps into the annular groove 19 made on the piston 13. The projectile 1 with the shank 3, having received acceleration through the piston 13 from the operation of the powder gases of the capsule sleeve 6, moves further by inertia in the barrel 24, where the obturation girdle 2 is bitten in the conical bevel 31 of the groove 2. In the process of biting the obturating girdle 2 in the conical bevel of 31 grooves of the barrel (or in the conical bevel for smoothness of trunks without rifling), the projectile 1 decelerates, as a result of which under the action of inertial forces the element (s) 23 are cut and the inertial load 22 is moved in the cavity of the liner 3. The movement of the inertial load 22 in the cavity of the liner 3 leads to an impact with the protrusion-tip 25 as a result of which either the initiator of the igniter, made in the form of a capsule sleeve 20, or the power supply 26 connected to the electric igniter 21 and triggering is triggered him. The products of combustion from the actuation of the capsule sleeve 20 or the electric igniter 21 through a gasdynamic connection made in the form of holes 27 initiate the igniter 7. If necessary, for the reliability of the initiation of the ignitor 7, an additional powder gun mount 29 can be used. The operation of the ignitor 7 leads to ignition of the propellant charge 8 Under the influence of the pressure of the powder gases of the igniter 7 and the propellant charge 8, the projectile 1 moves further along the barrel 24, finally crimping In this case, the obturating belt 2, which was previously bitten in the conical bevel 31, taking into account that the igniter 7 and the propellant charge 8 occur after biting and partial compression of the obturating belt 2 in the conical bevel 31, the energy efficiency of their combustion products increases, since the breakthrough of combustion products along the projectile and their impact on its side surface before biting and compressing the obturating belt, inherent in classical unitary shots, in which the flare of the projectile in the sleeve, moving the projectile, biting and compressing its obturating belt is excluded by the energy of the igniter powder and propellant, are excluded.

In addition, since when expanding the sleeve 5 and the initial movement of the projectile 1 in the barrel before biting its obturating belt 2, carried out due to the pressure energy of the powder gases from the operation of the capsule sleeve 6, an increase in the free volume occurs when the igniter 7 and the propellant charge 8 are initiated (decrease in charge density), which leads to a decrease in the maximum value and gradient of the increase in ballistic pressure in the sleeve when the propellant is triggered, and therefore, to reduce loads, The action on the projectile and its components and elements. This is especially important for guided missiles, which include electronic, optical and precision mechanics, most susceptible to mechanical damage. Further, under the action of the products of combustion of the igniter 7 and the propellant charge 8, the projectile 1 accelerates along the barrel 24 and flies out of it. Using the data of the firing method and unitary shot, while maintaining the required initial (muzzle) velocity of the projectile, reduces the maximum pressure acting on the projectile, or while maintaining the maximum pressure, it is possible to increase the mass of the propellant charge, and therefore the velocity of the projectile.

Thus, the proposed method of firing a gun and a unitary shot that implements it can improve the efficiency of using the energy of the products of combustion of the igniter and the propellant charge by pre-biting the igniter and triggering the propellant charge by biting the obturating belt of the projectile in the barrel, and also by increasing the reliability of the units and elements of the projectile by reducing the maximum value and gradient of the increase in ballistic pressure in the sleeve acting on the projectile.

Claims (4)

1. A method of firing a cannon with a unitary shot, including firing the capsule sleeve, initiating the igniter and propellant charge through a time delay, moving the projectile, biting and squeezing its obturation belt in the barrel and subsequent projectile departure from the barrel, characterized in that the igniter and the propellant charge carried out after moving the projectile and biting its obturating belt in the barrel, while moving the projectile and biting its obturating belt provide work pea gases isolated from igniter and propellant. 2. A unitary shot containing a shell with an obturating belt and a shank with an annular groove, a sleeve with a capsule bushing, an igniter and a propelling charge, in which a central channel is formed, a chamber located in the central channel, fastened to the bottom of the sleeve and in which the shell shank is placed, a pusher interacting with the shank of the projectile when the capsule sleeve is triggered, while the initiator of the igniter with its ignition unit, which is activated through the time delay about the operation of the capsule sleeve, characterized in that the pusher is made in the form of a piston with ring seals in contact with the inner surface of the chamber, while in the axial direction the piston contacts the shank of the projectile, and in the chamber, from the side facing the shank of the projectile, a piston trap is installed with a clamp, the igniter is made in the form of a toroidal cap with a powder composition placed in it, covering the shank of the projectile along an annular groove, the igniter initiator launch unit is nen as inertial load, is telescopically mounted in the cavity of the shell shank, fixed against longitudinal movement relative to the shank of the projectile element breakable at zakusyvanie obtyuriruyuschego girdle and crimping the barrel guns and activating the initiator or igniter power source connected to the ignition initiator. 3. A unitary shot according to claim 2, characterized in that the initiator of the igniter is made in the form of a capsule sleeve, and the inertial load is equipped with a protrusion-napolnik located opposite the capsule sleeve. 4. A unitary shot according to claim 2, characterized in that the igniter initiator is made in the form of a capsule sleeve placed on the end of the inertial load facing the bottom of the projectile, while a protrusion-cap is made in the shank of the projectile opposite the capsule sleeve.

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