RU2747873C1 - Marking cartridge with telescoped cartridge case - Google Patents

Abstract

FIELD: ammunition.

SUBSTANCE: invention relates to ammunition, namely to marking cartridges intended for training shooting. A marking cartridge with a telescoped cartridge case contains a cartridge case base with an initiation means, a movable element capable of moving along the cartridge case base, and bullet-shaped safety missile equipment installed in the recess of the movable element and partially protruding beyond the movable element. The safety equipment is equipped with elements interacting with the bore of the weapon when fired, containing a head and a bottom made of polymer material, connected by means of annular latches and jointly forming a cavity containing a coloring matter. The outer diameter of the head part of the projectile is less than the minimum diameter of the bore of the weapon. The bottom part of the projectile includes a front section protruding beyond the movable element and a rear section completely located in the recess of the movable element, separated by an annular protrusion, the outer diameter of which exceeds the inner diameter of the recess of the movable element and is equal to the maximum diameter of the barrel bore of the weapon. The outer diameter of the rear section of the bottom part of the missile equipment is less than the inner diameter of the recess of the movable element, and its outer cylindrical surface is equipped with elements interacting with the inner diameter of the recess of the movable element.

EFFECT: invention is aimed at increasing strength of the cartridge and increasing stability of the ballistic characteristics of the projectile equipment.

3 cl, 6 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 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 projectile equipment of the marking cartridges hits. 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.

Marking cartridges with a telescopic sleeve, designed for firing from self-loading weapons with screw grooves of the barrel bore, have become widespread, containing the base of the sleeve with an initiation means, a movable element capable of moving along the base of the case, and safety projectile equipment in the form of a bullet installed in the recess of the movable element and partially protruding beyond the movable element, equipped with elements that interact with the bore of the weapon when fired. Injury-safe missile equipment of marking cartridges contains a head part and a bottom part made of polymer material. The head and bottom parts of the projectile are connected by means of annular latches and together form a cavity containing a semi-liquid water-soluble dye. The hit of non-hazardous missile equipment both in hard and soft surfaces should lead to a violation of the integrity of the warhead of the missile equipment and the release of a dye that leaves a distinct color mark at the point of hitting the target.

A feature of marking cartridges is the low durability of missile equipment made of polymer material. The low durability of the projectile equipment determines the low durability of the marking cartridges and the low stability of the ballistic characteristics of the projectile equipment.

It must be borne in mind that the high strength of bullet cartridges intended for firing from weapons with screw grooves of the barrel bore is ensured by the tight installation of the bullet in the barrel of the sleeve and the annular crimping of the barrel of the sleeve, and for cartridges experiencing increased loads, additionally by punching the bullet in the barrel of the sleeve, circular rolling of the edge of the barrel sleeve or circular rolling of the bullet in the barrel of the sleeve.

It should also be borne in mind that the high stability of the ballistic characteristics of bullets of bullet cartridges intended for firing from weapons with screw grooves of the barrel bore is ensured by a stable force of extracting the bullet from the muzzle of the sleeve during firing, obturation of the powder gases and stable interaction of the bullet with the screw grooves of the barrel bore. Stable effort to extract a bullet from the muzzle of the case when fired is provided by calibrating the inner diameter of the muzzle of the case and annular crimping of the muzzle of the case. The obturation of the powder gases and the stable interaction of the bullet with the screw grooves of the barrel are provided by the interaction of the extended cylindrical section of the bullet with the grooves of the barrel and the conditions for cutting a metal bullet or a bullet with a metal shell into the rifling of the barrel in combination with the optimal ratio between the diameter of the cylindrical section of the bullet and the diameter of the barrel bore along the fields and grooves.

Technical solutions that ensure the strength of bullet cartridges and the stability of the ballistic characteristics of bullets are not applicable to marking cartridges, which are characterized by low strength of projectile equipment made of polymer material. The peculiarities of marking cartridges necessitate the use of technical solutions that ensure a solid installation of the projectile equipment in the recess of the moving element, a stable effort to remove the projectile equipment from the recess of the movable element when fired, obturation of the powder gases and stable interaction of the projectile equipment with the rifling of the barrel bore. The specified technical solutions should in aggregate ensure the strength of marking cartridges and the stability of the ballistic characteristics of the missile equipment.

When considering the conditions for the interaction of the projectile equipment of cartridges with the barrel of a weapon with screw grooves, it must be borne in mind that the dimensions of the barrel with screw grooves are characterized by the diameter of the barrel bore along the fields (minimum diameter of the barrel bore) and the diameter of the barrel bore along the grooves (maximum diameter of the barrel bore) ... A necessary condition for achieving stable ballistic characteristics of the projectile equipment of cartridges is the optimal ratio between the diameter of the projectile equipment, the maximum and minimum bore diameters.

Known marking cartridges with a telescopic sleeve Simunition FX Marking cartridges manufactured by General Dynamics Ordnance and Tactical Systems (trade name Simunition), designed for firing self-loading weapons with screw grooves of the barrel bore, containing a shortened sleeve with an initiation means, a movable element capable of moving along the base shells, powder propellant charge and safety throwing equipment [1].

Marking cartridges Simunition contain trauma-safe missile equipment in the form of a bullet, installed in the recess of the movable element and partially protruding beyond the movable element, equipped with elements interacting with the barrel bore of the weapon when fired, containing a head part and a bottom part made of polymer material, connected by means of annular latches and together forming a cavity containing the colorant. The head part of the projectile equipment is a thin-walled cap with a weakened head part. The bottom of the throwing equipment is a plug-in plug that closes the hole in the back of the cap. The element of the projectile equipment interacting with the barrel of the weapon when fired is the entire lateral cylindrical surface of the head of the projectile equipment.

The Simunition Product Catalog contains marking cartridges of 9 mm FX caliber, intended for firing from self-loading short-barreled weapons with screw-grooved bore [1]. The dimensions of the cartridges, the dimensions of the chamber and the bore of the 9 mm FX caliber weapons are specified in Table IV of the Permanent International Commission (PMC) of the Brussels Convention on the Mutual Recognition of Test Marks for Handguns. According to the data given in Table IV of the secondary armament, the diameter of the head part of the projectile equipment for cartridges of 9 mm FX caliber is greater than the diameter of the barrel bore of the weapon along the fields, but less than the diameter of the barrel bore of the weapon along the rifling [2]. Thus, when firing with Simunition marking cartridges, the entire lateral cylindrical surface of the head of the projectile equipment interacts with the barrel of the weapon, while there is a gap between the lateral cylindrical surface of the head of the projectile and the maximum diameter of the barrel bore.

Known marking cartridges, which are implemented technical solutions used in marking cartridges Simunition [3-12].

The disadvantages of Simunition marking cartridges are low strength and low stability of the ballistic characteristics of the projectile equipment.

The low durability of Simunition marking cartridges is due to the low durability of injury-safe missile equipment. The low strength of the missile equipment excludes the possibility of its strong attachment in the recess of the moving element. Even a slight force applied to the protruding part of the projectile can cause the projectile 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 low stability of the ballistic characteristics of the projectile equipment of the Simunition marking cartridges is due to the low stability of the effort to extract the projectile from the recess of the moving element during firing, insufficient obturation of the propellant gases and the low stability of the interaction of the projectile with the barrel bore with screw grooves. Insufficient obturation of powder gases when firing with Simunition marking cartridges is due to the low strength of the head part of the projectile equipment and the ratio between the diameter of the head part of the projectile equipment and the rifling diameter of the barrel bore. The interaction of the lateral cylindrical surface of a thin-walled cap made of a polymer material with screw grooves of the barrel bore is accompanied by crushing, deformation, disordered indentation into the screw grooves, tearing off of cap fragments, breakthrough of powder gases, tearing of the cap from the grooves and, by definition, is unstable. The low stability of the ballistic characteristics of the projectile equipment of the Simunition marking cartridges is aggravated by the stuck of the torn off cap fragments in the rifling of the barrel and their influence on the firing characteristics during subsequent shots.

The Simunition Product Catalog contains the kinetic energy of the projectile equipment 3.0-5.6 J and the firing accuracy of 9 cm at a range of 7.6 m for 9 mm FX Marking cartridges designed for firing self-loading short-barreled weapons of 9 mm FX [ one]. The specified deviation of the kinetic energy of the missile equipment 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 closest to the proposed cartridge are Telescopic Sleeve Marking Cartridges Force on Force Marking Rounds manufactured by Vista Outdoor Operations (trade name Force on Force), designed for firing self-loading weapons with screw grooves of the barrel bore, containing a sleeve with an initiator, a movable element, capable of moving along the base of the cartridge case, and safety throwing equipment [13].

Force on Force marking cartridges contain traumatic projectile equipment in the form of a bullet, installed in the recess of the movable element and partially protruding beyond the limits of the movable element, equipped with elements interacting with the barrel bore of the weapon when fired, containing a head part and a bottom part made of polymer material, connected by means of annular latches and together forming a cavity containing the colorant. The head part of the projectile equipment is a thin-walled cap with a weakened head part. The bottom part of the missile equipment is an element, the rear cylindrical part of which is installed in the recess of the movable element. The elements of the projectile equipment interacting with the bore of the weapon when fired are a thin copper ring installed in the recess of the bottom part of the projectile equipment, and a narrow annular protrusion made on the outer surface of the head part of the projectile equipment.

In the information materials Force on Force Training Rounds, marking cartridges of 5.56 mm caliber are indicated, intended for firing from self-loading long-barreled weapons with screw rifling of the bore [13]. The dimensions of the cartridges, the dimensions of the chamber and the barrel bore of 5.56 mm weapons (a military analogue of the civilian caliber 223 Rem.) Are listed in Table I of the Permanent International Commission (PMC) of the Brussels Convention on the Mutual Recognition of Test Marks for Handguns. In accordance with the data given in Table I of the PMK, the diameter of a thin copper ring and a narrow annular protrusion for cartridges of 5.56 mm caliber is greater than the diameter of the gun barrel along the fields and is larger than the diameter of the gun barrel along the rifling [14]. Thus, when firing Force on Force marking cartridges, a thin copper ring and a narrow annular protrusion, the diameter of which exceeds the maximum diameter of the barrel bore, interact with the barrel of the weapon.

Known marking cartridges, which are implemented technical solutions used in marking cartridges Force on Force [15-19].

The disadvantages of Force on Force marking cartridges are low strength and low stability of the ballistic characteristics of the projectile equipment.

The low strength of Force on Force marking cartridges is due to the low strength of injury-safe missile equipment. The low strength of the projectile equipment excludes the possibility of its strong attachment in the recess of the moving element.

The low stability of the ballistic characteristics of the projectile equipment of the Force on Force marking cartridges is due to the low stability of the effort to extract the projectile from the recess of the moving element when fired, insufficient obturation of the gases formed during the combustion of the initiating composition, and the low stability of the interaction of the projectile equipment with the barrel bore with screw grooves. Insufficient obturation of powder gases when firing with Force on Force marking cartridges is due to the low strength of a thin copper ring and a narrow annular protrusion, as well as the ratio between the diameter of a thin copper ring and a narrow annular protrusion and the diameter of the barrel bore along the grooves. The interaction of a thin copper ring with screw grooves of the barrel bore is accompanied by crushing, deformation of the ring, gas breakthrough, stripping from the grooves and, by definition, is unstable. According to the information materials Force on Force Training Rounds [13], the main purpose of a thin copper ring is to remove plastic fragments from the barrel screw threads that are stuck as a result of the interaction of the screw threads with the annular projection of the head of the projectile equipment. The interaction of a narrow annular protrusion, made on the outer surface of the head part of the missile equipment, with screw grooves of the barrel bore is accompanied by crushing, deformation, separation of fragments of a narrow annular protrusion, gas breakthrough, stripping from the grooves and, by definition, is unstable. The loads acting on the narrow annular protrusion when moving along the bore are applied to the head of the projectile equipment and can cause a violation of the integrity of the projectile equipment when fired.

The information materials Force on Force Training Rounds indicate the kinetic energy of the projectile equipment 1.9-3.7 J and the firing accuracy of 10.2 cm at a range of 7.6 m for 5.56 FoF Marking Round cartridges designed for firing from self-loading long-barreled weapons of caliber 5.56 mm [13]. 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.

The technical problems solved in the proposed invention are to increase the strength of marking cartridges and increase the stability of the ballistic characteristics of the projectile equipment.

These technical tasks are achieved by the fact that in a marking cartridge with a telescopic sleeve containing the base of the sleeve with an initiation means, a movable element capable of moving along the base of the sleeve, and a bullet-shaped safety throwable equipment installed in the recess of the movable element and partially protruding beyond the limits of the movable element equipped with elements interacting with the barrel bore of the weapon when fired, comprising a head and a bottom made of polymer material, connected by means of annular latches and jointly forming a cavity containing a coloring matter, the outer diameter of the head of the projectile is less than the minimum diameter of the barrel bore of the weapon, the bottom part of the projectile includes a front section protruding beyond the movable element, and a rear section completely located in the recess of the movable element, separated by an annular protrusion, the outer diameter of which exceeds the inner diameter of the recess of the movable element and is equal to the maximum diameter of the barrel bore of the weapon, while the outer diameter of the rear section of the bottom part of the projectile is less than the inner diameter of the recess of the movable element, and its outer cylindrical surface is equipped with elements interacting with the inner diameter of the recess of the movable element.

These technical tasks are achieved in that the outer cylindrical surface of the rear section of the bottom part of the missile equipment is equipped with elements made in the form of a set of annular protrusions, the diameter of which exceeds the inner diameter of the recess of the movable element.

These technical problems are achieved in that the outer cylindrical surface of the rear section of the bottom part of the missile equipment is equipped with elements made in the form of a set of longitudinal protrusions located along the generatrix, and the diameter of the circumscribed circle containing the tops of the protrusions exceeds the inner diameter of the recess of the movable element.

Figure 1 shows a marking cartridge with a telescopic sleeve before firing, with safety throwing equipment with elements made in the form of a set of annular protrusions.

Figure 2 shows a marking cartridge with a telescopic sleeve before firing, with safety throwable equipment with elements made in the form of a set of longitudinal protrusions.

Figure 3 shows the safety missile equipment of the marking cartridge.

Figure 4 shows the safety throwing equipment of the marking cartridge with elements made in the form of a set of annular protrusions.

Figure 5 shows the safety throwing equipment of the marking cartridge with elements made in the form of a set of longitudinal protrusions.

Figure 6 shows a marking cartridge with a telescopic sleeve after a shot.

Before the shot, the marking cartridge with a telescopic sleeve contains (Fig. 1, Fig. 2) a liner base with an initiation means 1, a movable element 2 capable of moving along the liner base 1, and an injury-safe missile equipment in the form of a bullet 3 installed in the recess of the movable element 2 and partially protruding beyond the movable element. Before the shot, the movable element 2 is in the rear position, in which the rear end of the movable element is pressed against the flange of the base of the sleeve 1.

Trauma-safe missile equipment of the marking cartridge (figure 3) contains a head part 4 and a bottom part 5, made of polymeric material, connected by means of annular latches and jointly forming a cavity containing a dye 6. The bottom part of the missile equipment includes front 7 and rear sections 8, separated by an annular ledge 9.

The outer diameter of the rear section of the bottom of the missile equipment d1 (Fig. 4, Fig. 5) is less than the inner diameter of the recess of the movable element D (Fig. 6).

Elements on the outer cylindrical surface of the rear section of the bottom of the missile equipment can be made (Fig. 4) in the form of a set of annular protrusions, while the diameter of the annular protrusions d2 exceeds the inner diameter of the recess of the movable element D (Fig. 6).

Elements on the outer cylindrical surface of the rear section of the bottom part of the missile equipment can be made (Fig. 5) in the form of a set of longitudinal protrusions located along the generatrix, while the diameter of the circumscribed circle d2 containing the tops of the longitudinal protrusions exceeds the inner diameter of the recess of the movable element D (Fig. .6).

Increasing the strength of the marking cartridge is provided by the ratio between the outer diameter of the rear section of the bottom part of the missile equipment and the inner diameter of the recess of the movable element, as well as the presence of elements on the outer cylindrical surface of the rear section of the bottom of the missile equipment interacting with the inner diameter of the recess of the movable element.

The ratio between the diameter of the rear section of the bottom part of the missile equipment and the inner diameter of the recess of the moving element eliminates the influence of the deviation of the values of the diameters of the rear section of the bottom part of the missile equipment and the internal diameter of the recess of the moving element on the strength of the installation of the missile equipment in the recess of the moving element. These technical solutions, in combination with the presence of elements on the outer cylindrical surface of the rear section of the bottom part of the missile equipment, interacting with the inner diameter of the recess of the movable element, ensure the strength of the cartridge, the strength of the installation of the projectile equipment in the recess of the movable element and the stability of the force of installation of the projectile in the recess of the movable element.

The strength of the installation of the projectile equipment in the recess of the movable element and the stability of the installation effort of the projectile equipment are provided by partial deformation of the rounded surfaces of the elements interacting with the inner diameter of the recess of the movable element.

A shot with a marking cartridge is accompanied by the actuation of the initiation means and the combustion of the initiating composition. The gases formed during the combustion of the initiating composition create pressure, under the action of which the injury-safe missile equipment is removed from the recess of the movable element, the missile equipment moves along the weapon barrel bore and the missile equipment takes off from the barrel bore with the required initial velocity. In addition, under the action of the gas pressure, the moving element moves to the forward position.

After the shot (Fig. 6), the movable element 2 is in the forward position, in which the rear end of the movable element is displaced to the maximum distance from the flange of the liner base 1. The movement of the movable element to the front position is accompanied by an increase in the length of the liner and the transfer of the necessary impulse to the movable parts of the self-loading weapon for the functioning of the reloading mechanism.

An increase in the stability of the ballistic characteristics of the missile equipment is achieved due to the stability of the effort to extract the missile equipment from the recess of the moving element during firing, obturation of gases and the stability of the interaction of the missile equipment with the barrel bore with screw grooves.

A necessary condition for the stability of the ballistic characteristics of the projectile is such a ratio between the outer diameter of the head of the projectile and the minimum diameter of the weapon barrel, which excludes the interaction of the head of the projectile with the bore of the weapon.

The stability of the effort to extract the projectile equipment from the recess of the movable element during firing is ensured by the same technical solutions that ensure the stability of the effort of installing the projectile equipment in the recess of the movable element.

The stability of the effort to retrieve the missile equipment from the recess of the movable element during firing is also ensured by the stable installation depth of the missile equipment in the recess of the movable element, the value of which is determined by the position of the annular protrusion of the bottom part of the projectile equipment.

The obturation of gases and the stability of the interaction of the missile equipment with the barrel bore with screw grooves are provided by the presence of an annular protrusion of the bottom of the missile equipment, which interacts with the barrel bore when fired, and the ratio between the annular protrusion diameter and the maximum diameter of the weapon barrel bore.

The presence of the annular protrusion of the bottom part of the missile equipment, in combination with the ratio between the annular protrusion diameter and the maximum diameter of the weapon barrel bore, ensures the stable nature of the interaction of the annular protrusion with the screw grooves of the barrel bore when the missile equipment moves along the barrel bore, prevents crushing and deformation of the annular protrusion, gas breakthrough, stalling from the grooves.

The set of technical solutions implemented in the proposed cartridge provides an increase in the strength of marking cartridges and an increase in the stability of the ballistic characteristics of the projectile equipment.

INFORMATION SOURCES

1. Simunition Product Catalog. Training for the Real World. General Dynamics Ordnance and Tactical Systems. 2019.

2. Permanent International Commission (C.I.P.) for the Proof of Small-arms. Tables. Table IV: Pistol and revolver cartridges. Edition 2011.

3. Canadian Patent 2419861. Improved training cartridge.

4. European Patent 0521008. Frangible nonlethal projectile.

5. United States Patent 5035183. Frangible nonlethal projectile.

6. United States Patent 5359937. Reduced energy cartridge.

7. United States Patent 5492063. Reduced energy cartridge.

8. United States Patent 5677505. Reduced energy cartridge.

9. United States Patent 6439123. Training cartridge.

10. United States Patent 6575098. Practice cartridge.

11. United States Patent 8327767. Reduced energy training cartridge for straight blow back operated firearms.

12. WO Patent 1991014148 Frangible nonlethal projectile.

13. Product Specification Sheet. Force on Force Training Rounds. 5.56 mm FoF Marking Round. Revised 2019.

14. Permanent International Commission (C.I.P.) for the Proof of Small-arms. Tables. Table I: Rimless cartridges. Edition 2011.

15. United States Patent 9470492. Spin-stabilized non-lethal projectile with a shear-thinning fluid.

16. United States Patent 9494397. Polymer projectile having an integrated driving band.

17. United States Patent 9835426B2. Spin-stabilized non-lethal projectile with a shear-thinning fluid.

18. United States Patent 10088287. Spin-stabilized non-lethal projectile with a shear-thinning fluid.

19. United States Patent 10436560. Polymer projectile having an integrated driving band.

Claims (3)

1. Marking cartridge with a telescopic sleeve, containing the base of the sleeve with an initiation means, a movable element capable of moving along the base of the sleeve, and safety projectile equipment in the form of a bullet, installed in the recess of the movable element and partially protruding beyond the movable element, equipped with elements interacting with the barrel of the weapon when fired, containing a head and a bottom made of a polymer material, connected by means of annular latches and jointly forming a cavity containing a coloring matter, characterized in that the outer diameter of the head of the projectile is less than the minimum diameter of the barrel bore of the weapon, the bottom the missile equipment includes a front section projecting beyond the movable element and a rear section completely located in the recess of the movable element, separated by an annular protrusion, the outer diameter of which exceeds the inner diameter of the recess i of the movable element and is equal to the maximum diameter of the barrel bore of the weapon, while the outer diameter of the rear section of the bottom of the missile equipment is less than the inner diameter of the recess of the movable element, and its outer cylindrical surface is equipped with elements interacting with the inner diameter of the recess of the movable element. 2. Marking cartridge with a telescopic sleeve according to claim 1, characterized in that the outer cylindrical surface of the rear portion of the bottom part of the missile equipment is equipped with elements made in the form of a set of annular protrusions, the diameter of which exceeds the inner diameter of the recess of the movable element. 3. Marking cartridge with a telescopic sleeve according to claim 1, characterized in that the outer cylindrical surface of the rear portion of the bottom part of the projectile is equipped with elements made in the form of a set of longitudinal protrusions located along the generatrix, and the diameter of the circumscribed circle containing the tops of the protrusions exceeds the inner diameter of the recess of the movable element.

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