RU2678216C1 - Ammunition in case - Google Patents

Abstract

FIELD: weapons and ammunition.SUBSTANCE: invention relates to ammunition for artillery. Ammunition in the case, made with the possibility of placing in the breech of an artillery gun, contains two projectiles, located in the case one ahead of the other, powder propelling charges of the front and rear shells mounted inside the body behind the corresponding projectile, electrical ignition for igniting powder propelling charges of the front and rear shells in a given time sequence, installed on the inner surface of the body, respectively, between the bottom of the front projectile and the head of the rear projectile, and between its bottom and bottom of the body. Input of each electric fuse is connected by a wire with a corresponding electrical contact passing through the bottom of the case and electrically insulated from it, the circuit consisting of an electrical contact, connected by a wire with the input of an electric igniter, and a housing represent an electric ignition circuit of the corresponding electric igniter. Inside the body there is an annular protrusion for abutting the bottom of the rear projectile, which has sealing means, which is a section of the rear projectile skirt, made expandable in the radial direction when exposed to a load inside the body when the front projectile is fired. It is equipped with a “pin-cone” docking device for rigid connection of front and rear projectiles after their departure from the muzzle of an artillery gun, including a recess with a cylindrical nest in its lower part, corresponding in shape to the rear projectile head, made in the bottom of the front projectile, and a pointed pin mounted on the rear projectile head, corresponding to a cylindrical socket, as well as a shock absorber to reduce the impact pulse when docking shells and fixing elements of the pointed pin in a cylindrical socket. In this case, the propellant powder possesses a higher force than the projectile propellant powder, and the difference in the forces of the propellant propellants in the rear and front projectiles is determined from the possibility of their docking in the immediate vicinity of the muzzle.EFFECT: technical result is to increase the firing range.1 cl, 4 dwg

Description

The invention relates to defense equipment, namely to ammunition for artillery pieces.

A device for increasing the flight range of an artillery shell [1], containing the head and tail compartments, warhead, stabilizer blades and bottom gas generator producing gaseous products with a lack of oxidizer, in which the aft part of the tail compartment is made in the form of a telescopic structure, which includes two coaxial shells, the outer of which is made with the possibility of its axial movement along the outer surface of the inner shell, with the formation of a afterburner with an air intake roystvom to the thrust collar and fixation thereon, but this outer shroud includes a rear end face with a nozzle opening, which with a certain opening force is fixed rear cover.

The disadvantages of this device include a decrease in the power of the projectile at the target, the determining factor of which is a decrease in the mass of the projectile by an amount of about 10% due to burnout of the charge of the bottom gas generator and separation from the projectile of the bottom cover after it leaves the bore. In addition, the presence of an air intake device in the afterburner leads to an increase in the aerodynamic drag of the projectile, which reduces its effectiveness at the target.

The closest analogue to the claimed device is the ammunition in the housing, made with the possibility of placing in the breech of an artillery gun containing two shells located in the housing one in front of the other, propellant propellant charges of the front and rear shells mounted inside the housing behind the corresponding projectile, electric ignition for ignition powder propellant charges of the front and rear shells in a given time sequence mounted on the inner surface of the housing, respectively between the bottom of the front projectile and the head of the rear projectile, and between its bottom and the bottom of the body, and the input of each electric valve is connected by a wire with a corresponding electrical contact passing through the bottom of the body and electrically insulated from it. Moreover, the circuit consisting of an electrical contact connected by a wire to the input of the electric fuse and the casing is an electric ignition circuit of the corresponding electric fuse, while an annular protrusion is made inside the casing for stopping the bottom of the rear projectile, having sealing means representing the portion of the rear projectile skirt, configured to expansion in the radial direction when exposed to a load inside the shell when firing a front projectile [2].

The use of the known device, which is an ammunition in the hull, containing two shells located one in front of the other in the hull, made with the possibility of placing artillery pieces in the breech, made it possible to ensure its high rate of fire when firing two shells one after another, amounting to 4,500 rounds per minute. due to the exclusion of the charging mechanism with moving parts, feeding separately shells to the breech.

Another factor ensuring high rate of fire is that the ignition of the propellant charge of the rear projectile is made almost immediately after the propellant of the front projectile is ignited while it is still moving in the gun barrel.

The disadvantages of such a device include insufficient firing range, low projectile power at the target due to its low mass, and also the high ratio of the mass of the gun to the mass of the shell, which reduces the mobility of the gun while ensuring high projectile power. These shortcomings will not occur if such ammunition in the hull is designed to be placed in the breech of an artillery gun, contains two shells located in the hull one in front of the other, propellant propellant charges of the front and rear shells mounted inside the hull behind the corresponding projectile, electrostocks for igniting the powder propelling charges of the front and rear shells in a given time sequence mounted on the inner surface of the housing, respectively, between the bottom of the front the projectile and the head of the rear projectile, and between its bottom and the bottom of the casing, and the input of each electric fuse is connected by a wire with a corresponding electrical contact passing through the bottom of the casing and electrically isolated from it. The circuit, consisting of an electrical contact connected by a wire to the input of the electric fuse and the body, is an electrical ignition circuit of the corresponding electric fuse, while an annular protrusion is made inside the body for stopping the bottom of the rear projectile, having sealing means representing the portion of the rear projectile skirt, configured to expansion in the radial direction when exposed to a load inside the shell when firing a front projectile.

According to the claimed invention, the ammunition is equipped with a “pin-cone” type docking device for rigidly connecting the front and rear shells after they take off from the muzzle of an artillery gun, including a receiving cone with a cylindrical socket at its apex, made at the bottom of the front shell, and a pointed pin mounted on the head of the rear projectile on its axis, as well as a shock absorber to reduce the shock impulse during docking and pin fixing elements in the cylindrical socket, while the propellant charge is rear the projectile has a higher force than the propellant propellant charge of the front projectile, while the propellant propellant charge of the rear projectile has a higher force than the propellant propellant charge of the front projectile, and the difference in the forces of the propellant propellants of the rear and front projectiles is determined from the possibility of their docking in close proximity from the muzzle.

In addition, the side surface and the bottom of the cylindrical socket are covered with an electrical insulating layer, and a shock absorber is made inside the cylindrical socket, made in the form of a compression spring, one end of which is connected to the electrical contact of the electrical circuit of the front projectile coming out of the bottom of the cylindrical socket, and the second is connected to the electrically conductive disk placed in a cylindrical socket with the possibility of axial movement, which, when the front and rear projectiles are docked, is in contact with the electric the tact of the electrical circuit of the rear projectile, extending from the center of the pointed pin and insulated from it, while the electrical contacts of the electrical circuit of the front projectile, the compression spring, the conductive disk, the electrical contact of the electrical circuit of the rear projectile and the mass of the front and rear shells rigidly interconnected represents electrical communication between the shells, and the fixing elements of the pointed pin in the cylindrical socket are made in a recessed spring-loaded ball stop located in the hole made in the lateral surface of the cylindrical socket and corresponding to the ball stop of the annular groove on the pointed pin.

Distinctive features of the invention are:

- the ammunition in the case is equipped with a “pin-cone” type docking device for rigidly connecting the front and rear shells after they take off from the muzzle of an artillery gun, including a receiving cone with a cylindrical socket at its apex, made at the bottom of the front shell, and a pointed pin mounted on the head of the rear projectile on its axis, as well as a shock absorber to reduce the shock momentum when docking and pin fixing elements in the cylindrical socket, while the propellant propellant charge of the rear projectile has more higher strength than the powder propellant charge of the projectile front;

- the lateral surface of the cylindrical socket and its bottom are covered with an electrical insulating layer and a shock absorber is placed inside it, made in the form of a compression spring, one end of which is connected to the electrical contact of the electrical circuit of the front projectile, coming out of the bottom of the cylindrical socket and insulated from it, and the second is connected to the contact a disk;

- the difference in the power of the propellant propellant charges of the rear and front shells, which are energy sources for communicating to the shells the necessary speeds, is determined from the possibility of their docking in the immediate vicinity of the muzzle section.

In addition, the side surface and the bottom of the cylindrical socket are covered with an electrical insulating layer, and a shock absorber is made inside the cylindrical socket, made in the form of a compression spring, one end of which is connected to the electrical contact of the electrical circuit of the front projectile coming out of the bottom of the cylindrical socket, and the second is connected to the electrically conductive disk placed in a cylindrical socket with the possibility of axial movement, which, when the front and rear projectiles are docked, is in contact with the electric the tact of the electrical circuit of the rear projectile, extending from the center of the pointed pin and insulated from it, while the series-connected electrical contacts of the electrical circuit of the front projectile, the compression spring, the conductive disk, the electrical contact of the electrical circuit of the rear projectile and the mass of the front and rear shells rigidly connected electrical communication between the shells, and the fixing elements of the pointed pin in the cylindrical socket are made in e recessed spring-loaded ball detent disposed in a hole formed in a side surface of the cylindrical socket and a corresponding annular groove ballpoint stopper on the sharpened pin.

Supply of ammunition in the hull with a pin-to-hull type docking device for rigidly connecting the front and rear shells after they take off from the barrel of the artillery gun, and also that the propellant propellant charge of the rear projectile has a higher force than the propellant propellant charge of the front projectile the difference in the power of the propellant propellant charges of the rear and front shells, which are energy sources for communicating to the shells the required speeds, is determined from the possibility of ensuring their docking in edstvennoy vicinity of the muzzle, enabled the departure from the barrel guns composite shell formed directly after departure from rigidly connected front and rear shells munition having a total weight of them with the same caliber. Therefore, the kinetic energy of the composite projectile is 2 times higher than the projectile of the known device, which leads to a significant increase in the flight range of the composite projectile.

Another factor in increasing the flight range of a composite projectile is an almost 2-fold increase in its length compared to a single projectile, which allows increasing the elongation of the head of the composite projectile λ = X _mid / D _mid (X _mid is the distance to the _mid -section having a diameter D _mid ) to the optimum value of λ _opt , which is 9 ± 2, at which the aerodynamic drag coefficient of the composite projectile C _{x is} minimal [3]. This also increases the projectile power at the target and decreases the ratio of the mass of the gun to the mass of the projectile.

The shock absorber of the docking device in the form of a compression spring placed in a cylindrical socket, one end of which is connected to an electrical contact of the electrical circuit of the front projectile coming out of the bottom of the cylindrical socket and electrically isolated from it, and the second is connected to an electrically conductive disk placed in a cylindrical socket with the possibility of axial movement which, in the docked position of the front and rear shells, is in contact with the electrical contact of the electrical circuit of the rear shell extending from the center of the pointed pin and electrically insulated from it, made it possible to ensure electrical communication between the docked shells. As a result of which it became possible to carry out their simultaneous detonation using electric fuses at a given point in the flight path of the composite projectile.

The implementation of the fixing elements of the pointed pin in the cylindrical socket in the form of a recessed spring-loaded ball stopper located in the hole made in the lateral surface of the cylindrical socket corresponding to the ball stopper of the annular groove on the pointed pin made it possible to rotate the pin around its longitudinal axis in the cylindrical socket at the initial moment of the front and rear shells with different rotation speeds when exiting the muzzle.

In FIG. 1 shows a General view of the ammunition in the housing. In FIG. Figure 2 shows a general view of the front and rear rounds of ammunition docked between themselves after they take off from the muzzle of an artillery gun. In FIG. 3 shows the remote element A with the nodes of the docking device after docking the front and rear shells. In FIG. 4 shows graphs 1, 2 of the motion paths obtained taking into account air resistance, respectively, of a composite projectile weighing 2m, consisting of rigidly connected front and rear shells, and a single projectile mass m of the prototype device.

The proposed device contains (Fig. 1) a housing 1 made with the possibility of placing in the breech of an artillery gun (not shown), front 2 and rear 3 shells located in the housing 1, propellant propellant charges of the front shell 4 and rear shell 5 mounted inside case 1 behind the shells, respectively 2 and 3, as well as electrozapalami 6 and 7 for igniting powder propellant charges 4 and 5, respectively, in a given time sequence. Electric fuses 6 and 7 are installed on the inner surface of the housing 1, respectively, between the bottom of the front projectile 2 and the head of the rear projectile 3 and its bottom and the bottom of the housing 1. The inputs of the electrical fuses 6 and 7 are indicated by the corresponding electrical contacts 10 and 11, passing through the bottom of the housing 1 and electrically insulated From him. Moreover, the circuit, consisting of electrical contacts 10 and 11, connected by wires 8 and 9, respectively, with the outputs of the electric valves 6 and 7, and the housing 1 are the electrical ignition circuits of these electric valves. At the same time, an annular protrusion 12 is made inside the housing 1 for abutting the bottom of the rear projectile 3, having sealing means representing a portion of the skirt 13 of the rear projectile 3, made expandable in the radial direction when exposed to a load inside the housing 1 when firing the front projectile 2.

In FIG. 2 shows the position of the docked front 2 and rear 3 shells after their departure from the muzzle.

The ammunition in the case is equipped with a pin-cone type docking device for rigidly connecting the front 2 and rear 3 shells after they take off from the muzzle of an artillery gun (not shown), including a recess 14 with a cylindrical socket 15 in its lower part, corresponding in shape to the head a rear projectile 3, made in the bottom of the front projectile 2, and a pointed pin 16 mounted on the head of the rear projectile 3, corresponding to the cylindrical socket 15, as well as a shock absorber 18 (Fig. 3) to reduce the shock moment when docking shells 2 and 3, and the fixing elements of the pin 16 in the cylindrical socket 15.

Docking devices of this type are presented in [4]. The lateral surface and the bottom of the cylindrical socket 15 are covered with an electrical insulating layer 17 (Fig. 3), and inside it there is a shock absorber 18 made in the form of a compression spring, one end of which is connected to the electrical contact of the electrical circuit of the front projectile 19 emerging from the bottom of the cylindrical socket 15 and electrically insulated from it, and the second is connected to an electric output disk 20 placed in a cylindrical socket 15 with the possibility of axial movement, the electrically conductive disk 20 after docking the front 2 and rear 3 shells (Fig. 3) to interacts with the electrical contact of the electrical circuit of the rear projectile 21 extending from the center of the pointed pin 16 and electrically isolated from it. In this case, the electrical contact 19, the compression spring 18, the electrically conductive disk 20, the electrical contact 21 and the mass of the front 2 and rear 3 shells rigidly interconnected between the shells 2 and 3 are connected in series, representing the electrical connection between the pointed pin 16 in the cylindrical nests 15 are made in the form of a recessed spring-loaded ball stopper 22 located in a hole made in the lateral surface of the cylindrical socket 15 and corresponding to the annular ball stopper 22 the grooves 23 on the pointed pin 16. The propellant powder 5 of the rear projectile 3 has a higher force than the propellant powder 4 of the front projectile 2, and the difference in the power of the propellant propellants 5 and 4 of the rear 3 and the front 2 shells, respectively, is an energy source for communicating to shells 3 and 2 the necessary speeds, determined from the possibility of their docking in the immediate vicinity of the muzzle.

When fired, the propellant propellant charge 4 of the front projectile 2 is ignited, and then, while the front projectile 2 is still moving in the gun’s barrel, the propellant propellant charge 5 of the rear projectile 3 is ignited by supplying electrical signals to the electrical contacts 10 and 11 of the corresponding ignition circuits of the electric fuses 6 and 7 from the mechanisms for producing a shot of electric action, which allows firing with two shells - front 2 and rear 3 - with a burst rate of 4500 you trill min. Moreover, at the moment of ignition of the propellant propellant charge 4 under the action of high pressure of the powder gases, the portion of the skirt 13 of the rear projectile 3 is shifted back along its conical part, expanding in the radial direction, and jammed the projectile 3, making tight contact with the inner wall of the housing 1, which eliminates breakthrough of pressurized gases to the powder propellant charge 5.

Thus, after sequential ignition of propellant propellant charges 4 and 5 by powder gases, the front 2 and rear 3 shells in the gun barrel are accelerated. Due to the fact that the propellant powder 5 has a higher force than the propellant powder 4, the difference in the forces of the propellant propellants 5 and 4 being determined from the possibility of mating shells 2 and 3 in the immediate vicinity of the muzzle, when projectiles 2 and 3 exit from it, the rear projectile 3 is reported to have a higher speed than the front projectile 2 and the rear projectile 3 catches up with the front projectile 2 at a minimum distance from the muzzle, which allows for the attachment of a pointed pin when docking shells 2 and 3 16 into a cylindrical seat 75 with minor probable radial deviations.

According to [5] in existing artillery systems, the ratio of the probable radial deviation B _b to the distance from the muzzle end X (B _b / X) can be 1/3000. For example, at X = 300 cm B _b will not exceed 1 mm. After this, the docking of the shells 2 and 3 begins, and due to the difference in their speeds, the pointed pin 16 slides into the cylindrical socket 15. In this case, the electrical contact 21 exiting from the center of the pointed pin 16 abuts against the electrically conductive disk 20 connected to the spring 18, during compression of which the shock impulse arising when the shells 2 and 3 are joined is extinguished. The axial movement of the pointed pin 16 relative to the cylindrical socket 15 stops after the spring-loaded ball stopper 22 enters the annular groove 23 on the pointed th pin 16. Moreover, at the beginning it is possible to rotate the docking spike pin 16 relative to the stopper ball 22, which occurs due to the difference of rotation speeds shells 2 and 3 as they exit from the muzzle.

Thus, after the shells 2 and 3 are joined directly at the muzzle end, a composite shell is formed consisting of two rigidly connected shells 2 and 3, having a common electrical communication, consisting of a series-connected electrical contact 19, a compression spring 18, an electrically conductive disk 20, an electrical contact 22 and the masses of shells 2 and 3 rigidly interconnected.

The flight range of a composite projectile weighing 2m, made for the developed ammunition design, and a single projectile mass m of a standard design taking into account air resistance, was estimated. For this purpose, the movement of a composite projectile with a mass of 2m equal to 1 kg is considered, to which the initial velocity V ₀ = 650 m / s at an angle α _{0 of} 45 ° to the horizon is communicated.

The differential equation of motion of this projectile in a Cartesian coordinate system with the horizontal axis OX and the vertical axis OU is as follows:

where ρ is the density of air (p = 1.225 kg / m ³ );

With _p - aerodynamic drag coefficient (taking into account [3] With _p = 0.3);

δ is the midsection sectional area of the composite projectile, which for a 30 mm caliber projectile was 7.068,010 ^-4 m ² ;

.V is the resulting velocity of the projectile,

.

The trajectory of the composite projectile was determined as a result of the numerical solution of the system of differential equations (1) by the Runge-Kutta method according to the developed software for computers in the FORTRAN language.

Further, with the help of the developed program, a system of differential equations was described that describes the motion of a single projectile, which has a similar form with system (1). In this case, the system of differential equations of motion of a single projectile differed from system (1) by only one parameter (mass of a single projectile m = 0.5 kg). After numerically solving the system of differential equations of motion for a single projectile, its flight path was constructed.

Graphs of the trajectories of motion 1, 2, respectively, of a composite projectile of mass 2m and a single projectile of mass m are shown in FIG. four.

From the consideration of the obtained trajectories, it follows that the flight range of a composite projectile made for the developed ammunition design is 10257 m. It significantly (more than 60%) exceeds the flight range of a single projectile of a standard design, which is 6341 m. Along with this, it increases significantly and the power of the projectile’s action on the target, the ratio of the mass of the gun to the mass of the shell decreases.

Bibliography

1. Patent RU 2486452, IPC F42B 10/38, 15/00, publ. 06/27/2013

2. Patent RU 2157499, IPC F41A 21/00, 21/06; F41F 1/00; F42B 5/03, publ. 10/10/2000

3. Krasnov, N.F. Aerodynamics of bodies of revolution. - M.: Mechanical Engineering 1964. - 572 p.

4. Syromyatnikov, B.C. Docking devices for spacecraft - M.: Mechanical Engineering, 1984. - 216 p.

5. Zhukov, I.I. Artillery weapons. - M.: Mechanical Engineering, 1975 .-- 420 p.

Claims (2)

1. Ammunition in the housing, made with the possibility of placing in the breech of an artillery gun, containing two shells located in the housing one in front of the other, propellant propellant charges of the front and rear shells mounted inside the housing behind the corresponding projectile, electrostocks for igniting the propellant propellant charges of the front and rear shells in a predetermined time sequence mounted on the inner surface of the housing, respectively, between the bottom of the front shell and the head of the rear sn a row, and between its bottom and the bottom of the case, and the input of each electric valve is connected by a wire with a corresponding electrical contact passing through the bottom of the case and electrically insulated from it, the circuit consisting of an electrical contact connected by a wire to the input of the electric valve and the case are electric the ignition circuit of the corresponding electric fuse, while an annular protrusion is made inside the body for stopping the bottom of the rear projectile having sealing means, which is a section of the skirt the bottom shell, made with the possibility of expansion in the radial direction under the influence of the load inside the shell when firing the front shell, characterized in that it is equipped with a docking device of the "pin-cone" type for rigid connection of the front and rear shells after they fly out of the muzzle of an artillery gun, including a recess with a cylindrical socket in its lower part, corresponding in shape to the head of the rear projectile, made in the bottom of the front projectile, and a pointed pin mounted on th the rear projectile, corresponding to the cylindrical socket, as well as a shock absorber to reduce the shock moment when the shells are joined and fixation elements of the pointed pin in the cylindrical socket, while the propellant propellant charge of the rear projectile has a higher force than the propellant propellant charge, the difference in the power of the powders propellant charges of the rear and front shells is determined from the possibility of their docking in the immediate vicinity of the muzzle. 2. The ammunition in the housing according to claim 1, characterized in that the side surface and the bottom of the cylindrical socket are coated with an insulating layer, and inside the cylindrical socket there is a shock absorber made in the form of a compression spring, one end of which is connected to the electrical contact of the electrical circuit of the front projectile, which leaves from the bottom of a cylindrical socket, and the second is connected to an electrically conductive disk placed in a cylindrical socket with the possibility of axial movement, which, when the front and rear sleep is in a docked position of poisons is in contact with the electrical contact of the electrical circuit of the rear projectile, coming from the center of the pointed pin and electrically isolated from it, while the electrical contacts of the electrical circuit of the front of the projectile, the compression spring, the conductive disk, the electrical contact of the electrical circuit of the rear projectile and the mass of the front and the rear shells are electrical communication between the shells, and the fixing elements of the pointed pin in the cylindrical socket is made in the form of a recessed spring-loaded ball stopper located in the hole made in the lateral surface of the cylindrical socket and corresponding to the ball stopper of the annular groove on the pointed pin.

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