RU2746003C1 - Method of self-loader shooting using marking cartridges and shooting system implementing it - Google Patents

Abstract

FIELD: weapons.SUBSTANCE: invention relates to weapons and in particular to a method of firing training ammunition. The method of self-loader shooting using marking cartridges includes the use of cartridges with safety projectile equipment containing a capsule with a coloring matter, firing a shot accompanied by the activation of the initiation means and ignition of the propellant propellant charge, moving the injury-safe projectile equipment along the barrel under the action of powder gases, obturation departure of non-hazardous missile equipment from the bore with the required initial velocity and the impact on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism. The method uses cartridges with safety projectile equipment containing a capsule with a coloring matter installed in a pallet made of elastic material, and a self-loading weapon with a section of a conical barrel bore narrowing in the direction from the chamber to the muzzle of the barrel, protect the capsule with a coloring matter from exposure to propellant gases and interaction with the walls of the barrel bore during firing, move the safety projectile equipment along the section of the conical barrel bore, inhibit the injury-safe projectile equipment when moving along the section of the bore of the conical shape and reduce the rate of decrease in the pressure of the powder gases due to the braking of the injury-safe projectile equipment. The obturation of the powder gases is ensured by the elastic deformation of the pallet. The impact on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism, is provided by the choice of the length of the section of the conical bore and the angle of the cone. The shooting system is also revealed.EFFECT: technical result consists in increasing the stability of the initial velocity of the projectile equipment and increasing the stability of the functioning of the weapon reloading mechanism.2 cl, 3 dwg

Description

The invention relates to training shooting, including training shooting of employees of anti-terrorist units in conditions that simulate the real conditions of anti-terrorist operations.

Training shooting with marking cartridges from self-loading weapons has become widespread, in which two groups of participants shoot at each other, followed by an analysis of the results of shooting at the color marks remaining in the places where the marking cartridges hit the projectile equipment. The use of personal protective equipment in combination with the low kinetic energy of the projectile equipment of the marking cartridges ensures the safety of training participants and a high degree of imitation of the real conditions of anti-terrorist operations.

The prerequisites for high training efficiency are:

- correspondence of the trajectories of the projectile equipment of the marking and bullet cartridges in the range of firing ranges typical for anti-terrorist operations;

- correspondence of the accompanying effects of the shot (sound of the shot, recoil of the weapon) when firing with marking and bullet cartridges;

- a pronounced pain effect when the projectile equipment of the marking cartridge hits.

The lack of a pronounced pain effect deprives the training participants of the necessary motivation and reduces the overall training efficiency.

Marking cartridges containing a sleeve with an initiation means, a propellant propellant charge, and an injury-safe projectile equipment containing a capsule with a coloring matter with a weakened head part made of a low-strength polymer material have become widespread. The hit of non-hazardous missile equipment on both hard and soft surfaces should lead to the opening of the weakened head part of the capsule with the coloring matter and the release of the coloring matter, leaving a distinct color mark at the point of hitting the target.

The peculiarity of the marking cartridges is the low mass and especially low kinetic energy of the projectile equipment. The mass of the projectile equipment of marking cartridges is significantly less than the mass of bullets of bullet cartridges of the corresponding caliber. The kinetic energy of the projectile equipment of marking cartridges intended for firing from short-barreled weapons is tens or hundreds of times less than the kinetic energy of bullets of bullet cartridges of the corresponding caliber, and the kinetic energy of the projectile equipment of marking cartridges intended for firing long-barreled weapons is hundreds or thousands of times less. less kinetic energy of bullets of bullet cartridges of the corresponding caliber. The low mass and especially low kinetic energy of the projectile equipment of the marking cartridges do not affect the functioning of non-self-loading weapons, however, they are of fundamental importance for the functioning of the self-loading weapon reloading mechanism. The impact on the moving parts of self-loading weapons when firing with marking cartridges is incomparably less than the impact on the moving parts of self-loading weapons when firing bullet cartridges and is insufficient for the functioning of the reloading mechanism.

Another feature of marking cartridges is the conflicting requirements for the strength of the colorant capsule. The dye capsule must maintain its integrity when handling cartridges, loading and unloading weapons in the magazine, removing cartridges from the chamber with weapon mechanisms, impacts and falls, as well as under the influence of loads accompanying the shot. At the same time, the capsule with the colorant must lose its integrity and ensure the release of the colorant when it hits both hard and soft surfaces. In this case, the loads on the capsule, arising under the influence of powder gases during a shot, and the loads arising from the interaction of the capsule with the barrel bore, can significantly exceed the loads arising when the capsule enters not only a soft, but also a hard surface.

For firing marking cartridges, both converted military, service and civilian self-loading weapons can be used, as well as specially designed weapons. Alteration of all types of weapons includes the replacement of the barrel to exclude the possibility of accidental loading and shooting with a bullet cartridge. In addition, when converting a weapon, it may also be necessary to replace the bolt, bolt return spring, magazine and other parts.

Thus, the method of firing marking cartridges from self-loading weapons and the shooting system that implements it must provide an effect on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism, when firing cartridges with a low mass and especially low kinetic energy of the projectile equipment. In addition, the method of firing marking cartridges from self-loading weapons and the shooting complex that implements it must ensure the integrity of the fragile capsule with the coloring matter under the influence of the loads accompanying the shot, and reliable opening of the capsule when it hits both hard and soft surfaces.

Known marking cartridges Simunition FX® Marking cartridges manufactured by General Dynamics Ordnance and Tactical Systems (trade name Simunition), designed for firing from self-loading weapons with a cylindrical barrel bore, containing a shortened sleeve with an initiator, a movable element installed inside the sleeve, powder throwing charge and safety projectile equipment containing a capsule with a dye [1].

The principal technical solution in Simunition marking cartridges is the use of a shortened sleeve with a movable element installed inside the sleeve. When fired under the action of powder gases, the movable element is displaced, accompanied by an increase in the length of the sleeve. The impact on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism, is provided by the transmission of the impulse created by the elongating sleeve.

Injury-safe throwing equipment in Simunition marking cartridges is a fragile capsule with a dye with a weakened head part, made of a low-strength polymer material. The capsule contains a cap with stress concentrators, filled with a semi-liquid water-soluble dye, and a plug-in stopper made of polymer material, which closes the hole in the back of the cap. When fired, the colorant capsule is exposed to the powder gases. The obturation of the powder gases is ensured by the adhesion of the capsule with the coloring matter to the walls of the barrel bore. The integrity of the fragile capsule with the coloring matter under the influence of loads accompanying the shot is achieved by reducing the power of the propellant propellant charge, smoothly increasing the pressure of the propellant gases in the space behind the fragile capsule, reducing the initial velocity and initial kinetic energy of the projectile equipment.

A known method of firing Marking cartridges Simunition from self-loading weapons, including the use of cartridges with safety projectile equipment containing a capsule with a coloring matter, firing a shot, accompanied by the triggering means of initiation and ignition of the propellant propellant charge, moving the traumatic projectile equipment through the gunpowder barrel under the action of the gunpowder powder gases, the departure of traumatic missile equipment from the bore with the required initial speed and the impact on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism.

According to the known method of firing Simunition marking cartridges from self-loading weapons, cartridges with a shortened sleeve with a movable element installed inside the sleeve are used, and a self-loading weapon with a cylindrical barrel bore, displace the movable element under the action of powder gases, increase the length of the sleeve, act on the capsule with powder gases with the coloring matter and move the capsule with the coloring matter along the barrel of a cylindrical shape, and the obturation of the powder gases is ensured due to the adherence of the capsule with the coloring matter to the walls of the barrel bore, and the effect on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism, is provided due to the transfer of impulse created by an extension sleeve.

In the well-known shooting system, which implements the method of firing Simunition marking cartridges, which includes a self-loading weapon and a marking cartridge with injury-safe missile equipment containing a capsule with a coloring matter, a weapon with a cylindrical shape of the barrel bore is used, and the diameter of the barrel bore is less than the outer diameter of the capsule with the coloring matter.

The disadvantages of the known method of firing Simunition marking cartridges from self-loading weapons and a small arms complex that implements it are:

- low training efficiency;

- low stability of initial speed and kinetic energy of traumatic missile equipment;

- low stability of the functioning of the mechanism of reloading weapons;

- low durability of cartridges;

- the complexity of the design and high cost.

The low efficiency of training when shooting with Simunition marking cartridges is due to the low degree of imitation of the real conditions of anti-terrorist operations. The need to preserve the integrity of a fragile capsule with a coloring matter under the influence of loads accompanying the shot requires a significant reduction in the power of the propellant propellant charge. The mass of the propellant propellant charge in the Simunition marking cartridges is many times reduced in comparison with the mass of the propellant propellant charge in bullet cartridges of the corresponding caliber. The low power of the propellant propellant charge, in combination with the low mass of the projectile equipment, results in a particularly low kinetic energy of the projectile equipment. The low mass of the projectile equipment in combination with a particularly low kinetic energy of the projectile equipment causes deterioration of the ballistic properties of the projectile equipment and the discrepancy between the trajectories of the projectile equipment of the marking and bullet cartridges. The especially low kinetic energy of the projectile equipment causes the absence of a painful effect when it hits a person, which deprives the training participants of the necessary motivation. In addition, the low power of the propellant propellant charge causes a weak sound of a shot and a weak recoil of the weapon.

The low stability of the initial velocity and kinetic energy of the projectile equipment when firing with Simunition marking cartridges is due to the low power of the propellant propellant charge, insufficient obturation of the powder gases between the sleeve and the moving element installed inside the sleeve, insufficient obturation of the propellant gases when the capsule with the coloring matter moves along the barrel bore.

In the Simunition Product Catalog, the kinetic energy of 3.0-5.6 J of projectile equipment is indicated for pistol marking cartridges of 9 mm caliber when firing from self-loading pistols [1]. The specified kinetic energy of the projectile equipment is unacceptably low, especially taking into account the use of personal protective equipment by the training participants. It should be borne in mind that, in accordance with the requirements of the Federal Law "On Weapons", the muzzle energy of a civilian firearm of limited damage should not exceed 91 J, and the muzzle energy of a service firearm of limited damage should not exceed 150 J. that, in accordance with the requirements of the Federal Law "On Weapons", a pneumatic weapon with a muzzle energy of no more than 3 J is not a weapon, it is purchased without a license and is not registered [2].

In accordance with the rules of Russian forensic medicine, the damaging effect of the missile equipment is determined by the specific kinetic energy, while the specific kinetic energy of 0.5 J / mm ² is a safe value that does not lead to a violation of the integrity of the human skin that is not protected by outer clothing [3] ... The specific kinetic energy of the projectile equipment of pistol marking Simunition cartridges of 9 mm caliber with a kinetic energy of 3 J and a diameter of 8 mm is about 0.06 J / mm ² , however, it should be taken into account that a fragile capsule with a dye with a weakened head part has the ability to deform, and its area upon impact increases significantly with a corresponding decrease in the specific kinetic energy.

The deviation of the kinetic energy of the missile equipment specified in the Simunition Product Catalog is unacceptably large and causes an unacceptable dispersion of the trajectories of the missile equipment, which greatly reduces the probability of hitting a target in the range of firing ranges typical for anti-terrorist operations.

The low stability of the functioning of the mechanism for reloading the weapon when firing with Simunition marking cartridges is due to the low stability of the impulse transmitted to the moving parts of the weapon. The low stability of the impulse transmitted to the moving parts of the weapon is due to the low power of the propellant propellant charge and insufficient obturation of the powder gases between the sleeve and the movable element installed inside the sleeve. The low stability of the impulse transmitted to the moving parts of the weapon determines the low stability of the functioning of the reloading mechanism and the high probability of weapon failures associated with the failure to remove the spent cartridge case, the failure of the cartridge in the chamber, the sticking of the cartridge and other anomalous phenomena during firing.

The low strength of Simunition marking cartridges is due to the low strength of the colorant capsule. The low strength of the capsule excludes the possibility of its strong attachment in the movable element installed inside the sleeve. Even a small force applied to the capsule can damage the weakened capsule head or cause the capsule to fall out of the cartridge. This drawback requires particularly careful handling of cartridges and causes a high probability of damage or violation of the integrity of cartridges when handling cartridges, loading and unloading weapons in the magazine, as well as when removing cartridges from the chamber with weapon mechanisms, impacts and falls.

The complexity of the design and the high cost of Simunition marking cartridges are due to the use of a shortened sleeve, the presence of additional structural elements that provide an effect on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism, and additional structural elements that ensure the integrity of the fragile capsule with the coloring matter due to the smooth increase in the pressure of the powder gases when fired.

Known marking cartridges intended for firing from self-loading weapons with a cylindrical bore, in which the technical solutions used in the Simunition marking cartridges are implemented [4-13].

Known marking cartridges intended for firing from self-loading weapons with a cylindrical bore, in which technical solutions are implemented, aimed at eliminating the disadvantages of Simunition marking cartridges [14-24, 26-29, 33, 34, 36, 37, 39]. All known marking cartridges contain a movable element mounted outside the sleeve.

To improve the obturation of gases inside the sleeve and increase the stability of the impact on the moving parts of the weapon, cartridges with a rubber sealing ring installed between the sleeve and the moving element are used [15-23, 27, 29, 30, 33, 36, 37].

To improve obturation of gases when moving projectile equipment along the bore, to increase the stability of the initial velocity and kinetic energy of projectile equipment, cartridges with projectile equipment are used, on the outer surface of which there are annular belts [19, 31, 33, 35-38].

To increase the stability of the initial speed and kinetic energy of the projectile equipment, cartridges with an additional means of initiation are used. These cartridges contain a rear initiation means, a front initiation means and an internal percussion mechanism designed to initiate the front initiation means when fired [20, 21, 23, 28, 34].

To increase the strength of the cartridges, cartridges with a metal capsule with a coloring matter are used, in the head of which a dome with slots is installed [25, 32, 34].

Known marking cartridges Force on Force Marking Rounds manufactured by Vista Outdoor Operations (trade name Force on Force), designed for firing self-loading weapons with a cylindrical barrel bore, with a rubber O-ring installed between the sleeve and the movable element, with throwing equipment, on the outer surface of which is made of annular belts [40].

There is a known method of firing Force on Force marking cartridges from self-loading weapons and a shooting complex that implements it, which have all the disadvantages of the method of firing Simunition marking cartridges and a shooting complex that implements it.

In the information materials Force on Force Training Rounds, the kinetic energy of 1.9-3.7 J of missile equipment is indicated for pistol marking cartridges of 9 mm caliber when firing from self-loading pistols [40]. The specified kinetic energy of the projectile equipment is unacceptably low, especially taking into account the use of personal protective equipment by the training participants. The specified deviation of the kinetic energy of the projectile equipment is unacceptably large and causes an unacceptable dispersion of the trajectories of the projectile equipment, which greatly reduces the probability of hitting the target in the range of firing ranges typical for anti-terrorist operations. In addition, the disadvantage of the method of firing Force on Force marking cartridges is the high cost due to the complexity of the design and the high cost of cartridges. The peculiarities of the technical solutions used exclude the possibility of manufacturing Force on Force cartridges using technologies for the production of small arms cartridges.

Known marking cartridges Man Marker Round manufactured by Ultimate Training Munitions (trade name MMR), designed for firing self-loading weapons with a cylindrical bore, with a rubber O-ring installed between the sleeve and the movable element, a rear initiation means, an internal percussion mechanism and a front a means of initiation. The cartridges contain projectile equipment containing a metal capsule with a dye and a ball installed inside the capsule, designed to squeeze out the dye under the action of inertial forces arising when the projectile hits the target. The dye-containing recess of the capsule is covered with a protective membrane. A three-beam dome made of polymer material is installed in the head of the capsule [41].

There is a known method of firing MMR marking cartridges from self-loading weapons and a shooting complex that implements it, which have all the disadvantages of the method of firing Simunition marking cartridges and a shooting complex that implements it.

In the Ultimate Training Munitions catalog, the average kinetic energy of 1.9 J of missile equipment is indicated for pistol marking cartridges of 9 mm caliber when firing from self-loading pistols [41]. The specified kinetic energy of the projectile equipment is unacceptably low, especially taking into account the use of personal protective equipment by the training participants. In addition, the disadvantage of the method of firing MMR marking cartridges is the high cost due to the complexity of the design and the high cost of the cartridges. MMR marking cartridges are complex products containing a large number of components and parts that are complex in design and high cost. The peculiarities of the technical solutions used exclude the possibility of manufacturing MMR cartridges using technologies for the production of small arms cartridges.

The closest to the proposed method is a method of firing marking cartridges from a self-loading weapon with a free breech, including the use of cartridges with injury-safe projectile equipment containing a capsule with a dye, firing a shot, accompanied by the triggering means of initiation and ignition of a powder propellant charge, movement of the projectile ammunition along the channel the barrel under the action of powder gases, obturation of powder gases, the departure of traumatic missile equipment from the barrel with the required initial velocity and the impact on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism [12].

According to the known method of firing marking cartridges from self-loading weapons with a free shutter, cartridges with a shortened sleeve with a movable element installed inside the sleeve are used, and a self-loading weapon with a cylindrical barrel bore, displace the movable element under the action of powder gases, increase the length of the sleeve, act with powder gases onto the capsule with the coloring matter and move the capsule with the coloring matter along the barrel bore of a cylindrical shape, moreover, the obturation of the powder gases is provided due to the adherence of the capsule with the coloring matter to the walls of the barrel bore, and the effect on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism, is provided due to transmission of the impulse created by the lengthening sleeve.

In the well-known shooting complex, which implements the method of firing marking cartridges from a self-loading weapon with a free breechblock, including a self-loading weapon and a marking cartridge with injury-safe missile equipment containing a capsule with a coloring matter, a weapon with a cylindrical shape of the barrel bore is used, and the diameter of the barrel bore is less than the outer diameter of the capsule with a coloring matter.

The disadvantages of the known method of firing marking cartridges from a self-loading weapon with a free bolt and a rifle complex that implements it are:

- low training efficiency;

- low stability of initial speed and kinetic energy of traumatic missile equipment;

- low stability of the functioning of the mechanism of reloading weapons;

- low durability of cartridges;

- the complexity of the design and high cost.

The technical problems solved in the proposed invention are to increase the efficiency of training, increase the stability of the initial speed and kinetic energy of traumatic missile equipment, increase the stability of the functioning of the weapon reloading mechanism, increase the strength of cartridges, simplify the design and reduce the cost.

The specified technical tasks are achieved by the fact that in the method of firing marking cartridges from self-loading weapons, including the use of cartridges with injury-safe missile equipment containing a capsule with a dye, firing a shot, accompanied by the triggering means of initiation and ignition of a propellant propellant charge, movement of a safety-free missile weapon channel under the action of propellant gases, obturation of propellant gases, the departure of traumatic missile equipment from the bore with the required initial velocity and the impact on the moving parts of the weapon, necessary for the functioning of the reloading mechanism, use cartridges with traumatic missile equipment containing a capsule with a coloring matter installed in the pallet, made of elastic material, and a self-loading weapon with a conical section of the barrel bore tapering from the chamber to the muzzle of the barrel, protect the capsule with paint m substance from the effects of powder gases and interaction with the walls of the barrel bore when fired, they move the safety throwable equipment along the section of the bore of the conical shape, inhibit the safety throwing equipment when moving along the section of the barrel bore of the conical shape and reduce the rate of decrease in the pressure of the powder gases due to the braking of the injury-safe missile equipment, and the obturation of the powder gases is provided due to the elastic deformation of the pallet, and the impact on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism, is provided due to the choice of the length of the conical bore section and the angle of the cone.

These technical tasks are achieved by the fact that in the shooting complex, which includes a self-loading weapon and a marking cartridge with a safety throwable equipment containing a capsule with a dye, in a marking cartridge, a dye capsule is installed in a pallet made of an elastic material, and the barrel bore of a self-loading weapon is made with a conical section tapering in the direction from the chamber to the muzzle of the barrel, the largest diameter of the barrel bore being less than the outer diameter of the pallet, and the smallest diameter of the barrel bore greater than the outer diameter of the capsule with the coloring matter.

A feature of the proposed method of firing marking cartridges from self-loading weapons and a small arms complex that implements it is the implementation of actions and the use of technical solutions related to the shooting complex as a whole, including marking cartridges and weapons, in contrast to the known methods of shooting marking cartridges and shooting complexes, in which actions are carried out and technical solutions are used related only to cartridges. The implementation of actions and the use of technical solutions related to the shooting complex as a whole opens up wide additional opportunities for varying the parameters that determine the interaction of the marking cartridge and self-loading weapons when fired, and allows you to balance the parameters of the shooting complex while simplifying the design and reducing the cost.

Practice shows that firing marking cartridges, characterized by a low mass of missile equipment, from self-loading weapons with a cylindrical barrel bore, does not fully balance the parameters of the small arms complex, even with a significant complication of the cartridge design. When firing marking cartridges from a self-loading weapon with a cylindrical barrel bore, the impact on the moving parts of the weapon due to the pressure pulse of the powder gases is not enough for the functioning of the reloading mechanism even if the mass of the propellant propellant charge of the marking cartridge is equal to or exceeds the mass of the propellant propellant charge of the bullet cartridge of the corresponding caliber. The low mass of the missile equipment of marking cartridges leads to an increase in the initial speed of the missile equipment, a rapid decrease in the pressure of the powder gases and the impossibility of reaching a pressure pulse of the powder gases necessary for the functioning of the self-loading weapon reloading mechanism.

Practice also shows that the most effective way to reduce the rate of decrease in the pressure of powder gases is to brake the projectile equipment while moving along the bore. It must be borne in mind that the pressure of the propellant gases reaches a maximum value in the case at the time of the shot and further decreases continuously as the projectile moves along the bore due to an increase in the volume in which the propellant propellant charge burns. The deceleration of the projectile equipment in the barrel bore can significantly reduce the rate of decrease in the pressure of the powder gases, multiply the impulse of the pressure of the powder gases and the corresponding effect on the moving parts of the weapon. The magnitude of the required impulse of the pressure of the powder gases, which provides the effect on the moving parts of the weapon, necessary for the functioning of the reloading mechanism, depends on the mass of the moving parts, the force of the return and mainspring, the stroke length of the moving parts and other parameters of the specific model of the weapon.

The peculiarities of firing with marking cartridges exclude the possibility of braking the projectile equipment due to the installation of partitions, protrusions, constrictions and other structural elements in the barrel bore that can cause deformation or destruction of a fragile capsule with a coloring matter. The most effective method of braking the missile equipment is the use of a weapon with a conical section of the barrel bore narrowing in the direction from the chamber to the muzzle of the barrel. By choosing the length of the section of the bore of the conical shape and the angle of the cone, the required impulse of the pressure of the powder gases and the corresponding effect on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism, can be achieved.

At the same time, firing marking cartridges from weapons with a conical bore section requires the use of marking cartridges with projectile equipment, including a pallet made of elastic material. The elastic properties of the pallet ensure the movement of the projectile equipment along the bore of the conical shape, protection of the fragile capsule with the coloring matter from the effects of powder gases and from interaction with the walls of the bore during firing. In addition, the elastic properties of the pallet ensure complete obturation of the powder gases.

The proposed method of firing marking cartridges from self-loading weapons is carried out as follows.

For firing, marking cartridges are used with traumatic throwable equipment containing a capsule with a coloring matter installed in a pallet made of elastic material, and a self-loading weapon with a conical-shaped barrel bore section narrowing in the direction from the chamber to the muzzle of the barrel.

The cartridge is placed in the chamber of the weapon and a shot is fired, accompanied by the activation of the initiation means and the ignition of the powder propellant charge. The propellant gases formed during the combustion of the propellant propellant charge create pressure, under the action of which the trauma-safe missile equipment moves along the barrel bore.

The capsule with the coloring matter is protected from the effects of powder gases and interaction with the walls of the barrel bore during firing by installing the capsule with the coloring matter in a pallet made of elastic material.

Injury-safe throwing equipment is moved along a section of the bore of a conical shape, tapering in the direction from the chamber to the muzzle of the barrel. The movement of non-hazardous missile equipment along the tapering section of the bore is accompanied by a constantly increasing resistance, deceleration of non-hazardous projectile equipment and a decrease in the rate of decrease in the pressure of propellant gases due to the deceleration of non-hazardous projectile equipment.

Obturation of powder gases during firing is provided due to the elastic deformation of the pallet.

The impact on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism, is provided by choosing the length of the section of the conical bore and the angle of the cone.

In the proposed shooting complex, a marking cartridge is used, in which a capsule with a coloring matter is installed in a pallet made of an elastic material, and a self-loading weapon, in the bore of which a conical section is made, tapering in the direction from the chamber to the muzzle of the barrel. The largest bore diameter is less than the outer diameter of the pallet, and the smallest bore diameter is greater than the outer diameter of the colorant capsule.

The use of a marking cartridge, in which the capsule with the coloring matter is installed in a pallet made of elastic material, ensures the movement of injury-safe missile equipment along the section of the conical bore and protects the capsule with the coloring matter from the effects of powder gases when fired. The ratio of the largest diameter of the bore and the outer diameter of the pallet ensures complete obturation of the powder gases. The ratio of the smallest diameter of the barrel bore and the outer diameter of the capsule with the coloring matter protects the capsule from interaction with the walls of the barrel bore when fired.

Shooting from a weapon with a section of the bore of the conical shape, tapering in the direction from the chamber to the muzzle of the barrel, provides a constantly increasing resistance when moving non-hazardous missile equipment along the barrel bore, deceleration of non-hazardous projectile equipment and a decrease in the rate of decrease in the pressure of propellant gases due to braking of the projectile ...

FIG. 1 shows the barrel of a weapon with a section of the bore of the conical shape before the shot, with a marking cartridge placed in the chamber.

FIG. 2 shows the barrel of the weapon with a section of the bore of the conical shape during the shot, in the process of moving the traumatic missile equipment along the section of the bore of the conical shape.

FIG. 3 shows a marking cartridge containing a sleeve with an initiation means 1, a propellant propellant charge 2 and a capsule 3 with a colorant 4 installed in a tray 5.

To implement the proposed method and use in the shooting complex, marking cartridges can be used, in which the technical solutions used in the marking cartridge are implemented [42].

The proposed method and the shooting system provide high training efficiency due to the correspondence of the trajectories of the projectile equipment of the marking and bullet cartridges in the range of firing ranges characteristic of anti-terrorist operations, the correspondence of the accompanying effects of the shot (the sound of a shot, the recoil of the weapon) when shooting with marking and bullet cartridges, the creation of a pronounced pain effect in humans upon hitting missile equipment of the marking cartridge. High training efficiency is achieved through the use of cartridges with a propellant propellant mass close to the mass of a propellant propellant charge of bullet cartridges of the corresponding caliber, the implementation of the principles of the reloading mechanism used in small arms, and the choice of the optimal initial velocity and kinetic energy of the projectile projectile of the marking cartridge.

The proposed method and the shooting system provide high stability of the initial velocity and kinetic energy of the projectile equipment due to the use of cartridges with a mass of propellant propellant charge close to the mass of propellant propellant charge of bullet cartridges of the corresponding caliber, and full obturation of propellant gases due to elastic deformation of the pallet made of elastic material.

The proposed method and the shooting system provide an increase in the strength of the marking cartridges due to the strong installation of the capsule with the coloring matter in the pallet made of elastic material. The installation of the capsule with the colorant in the pallet made of elastic material ensures a strong fastening of the capsule in the cartridge and excludes the possibility of the capsule falling out of the cartridge when handling cartridges, loading and unloading into the weapon magazine, removing cartridges from the chamber with weapon mechanisms, impacts and falls.

The proposed method and shooting complex provide simplicity of design and low cost of cartridges and weapons. Used marking cartridges contain a standard sleeve with an initiation means and a minimum number of elements, which are characterized by simplicity of design and low cost. Features of the technical solutions used provide the possibility of manufacturing cartridges using technologies for the production of small arms cartridges. The used self-loading weapon differs from the weapon intended for firing bullet cartridges only in the shape of the barrel bore.

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40. Product Specification Sheet. Force on Force Training Rounds. 9 mm FoF Marking Round. Revised 2019.

41. UTM Product Catalog v23.5.

42. Patent of the Russian Federation 2716666. Marking cartridge.

Claims (2)

1. A method of firing marking cartridges from a self-loading weapon, including the use of cartridges with safety projectile equipment containing a capsule with a coloring matter, firing a shot, accompanied by the triggering means of initiation and ignition of a propellant propellant charge, movement of a propellant propellant charge through the gas channel, under the action of propellant powder gases, the departure of a traumatic missile equipment from the bore with the required initial velocity and the impact on the moving parts of the weapon, necessary for the functioning of the reloading mechanism, characterized in that they use cartridges with traumatic missile equipment containing a capsule with a dye installed in a pallet made of elastic material, and a self-loading weapon with a conical section of the barrel bore tapering in the direction from the chamber to the muzzle of the barrel, protect the capsule with the coloring matter from the effects of p ore gases and interactions with the walls of the barrel bore when fired, move the non-hazardous projectile equipment along the section of the conical barrel bore, inhibit the injury-safe projectile equipment when moving along the section of the conical barrel bore and reduce the rate of decrease in the pressure of the propellant gases due to the inhibition of the injury-safe projectile equipment, and obturation powder gases are provided due to the elastic deformation of the pallet, and the effect on the moving parts of the weapon, which is necessary for the functioning of the reloading mechanism, is provided by choosing the length of the conical bore section and the angle of the cone. 2. A shooting system, including a self-loading weapon and a marking cartridge with a safety throwable equipment containing a capsule with a coloring matter, characterized in that the cartridge with a coloring matter is installed in a marking cartridge in a pallet made of elastic material, and the barrel bore of a self-loading weapon is made with a section conical shape, tapering in the direction from the chamber to the muzzle of the barrel, and the largest diameter of the barrel bore is less than the outer diameter of the pallet, and the smallest diameter of the barrel bore is greater than the outer diameter of the capsule with the coloring matter.

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