RU2348892C1 - Traumatic cartridge - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: present invention pertains to small arms ammunition. The cartridge has a hard case, igniter capsule, propellant charge and a spray spherical traumatic element made from elastic material, fixed in the case through circular deformation of the mouth of the case. The cartridge has optimum ratio of geometric dimensions, providing for stable ballistic characteristics, and possibility of using the cartridge for shooting from a broad spectrum of models of long-barrelled, short-barrelled, tubeless, self-loading and non-self loading weapons.

EFFECT: stable ballistic characteristics and possibility of using the cartridge for shooting from a broad spectrum of models of long-barrelled, short-barrelled, tubeless, self-loading and non-self loading weapons.

1 tbl, 3 dwg

Description

The invention relates to traumatic cartridges, in particular to cartridges containing a rigid sleeve, an igniter capsule, a propelling charge and a spherical traumatic element made of elastic material fixed in the sleeve by circular deformation of the barrel barrel.

Cartridges containing a rigid sleeve, an igniter capsule, a propellant charge and a spherical traumatic element made of elastic material fixed in the sleeve by circular deformation of the sleeve barrel are the most common traumatic cartridges for firing from pistols, revolvers, firing devices, as well as for firing from long-barreled smooth-bore firearms. The use of a rigid, as a rule, metal sleeve implies the strength of the sleeve, which retains geometric dimensions when installed in the sleeve of a missile element with the largest diameter exceeding the inner diameter of the sleeve. The spherical shape of the missile traumatic element determines the uniqueness of the traumatic effect, regardless of the angle of the meeting with the goal, taking into account possible bounces. The elastic material of the missile traumatic element allows to reduce the likelihood of causing serious harm to health, persistent disability of the target, death. Securing a missile traumatic element in a cartridge case by circular deformation of the cartridge case barrel is a generally accepted method for ensuring stable geometrical dimensions of cartridges, stable operation of reloading mechanisms of self-loading weapons and the convenience of loading non-self-loading weapons due to rounding of the cartridge case barrel, increasing the stability of pressure of powder gases by increasing the pressure of the powder gases and the completeness of combustion gunpowder during the passage of missile traumatic elements through the outlet of the sleeve with a diameter ohm smaller than the inner diameter of the sleeve.

Known traumatic cartridges containing a rigid sleeve, an igniter capsule, a propelling charge and a missile spherical traumatic element made of elastic material, fixed in the sleeve by circular deformation of the barrel barrel, for example, traumatic caliber cartridges. 380 ME Gum, 10 × 22T, 10 × 23T, 12/50 SAPL [1, 2].

A disadvantage of the known cartridges is the low stability of the ballistic characteristics, due to the lack of requirements for size ratios that determine the stability of the ballistic characteristics of the cartridges: the outer diameter of the cartridge, the inner diameter of the cartridge, the diameter of the missile element, the diameter of the outlet of the deformed part of the cartridge shell, the shape and dimensions of the deformed part of the cartridge cartridge cartridge.

The stability of the ballistic characteristics of traumatic cartridges is a broad concept that includes the stability of parameters such as loading density, pressure of powder gases, the initial speed of the missile elements, the shape of the missile elements, the dispersion of the trajectory of the missile elements, as well as the stability of the mechanisms of reloading self-loading weapons. In turn, the stability of the pressure of the powder gases is determined by the stability of the ballistic processes during the shot, as well as the stability of the state of the powder charge during storage and its protection from atmospheric factors. The stability of the ballistic characteristics of traumatic cartridges is largely determined by the optimal ratio of geometric dimensions: the outer diameter of the sleeve, the inner diameter of the sleeve, the diameter of the missile element, the diameter of the outlet of the deformed portion of the barrel of the sleeve, the shape and dimensions of the deformed portion of the barrel of the sleeve.

The stability of ballistic characteristics, in the first place, the stability of the initial speed of missile traumatic elements, is of particular importance for ensuring the effectiveness and safety of traumatic weapons. The increased speed of the missile traumatic element increases the danger of the weapon, is capable of causing serious harm to health and the permanent loss of working ability of the target, can cause death. The reduced speed of the missile traumatic element reduces the effectiveness of the weapon. According to existing ideas, the effectiveness of the traumatic effect is determined by the kinetic energy of the propelled traumatic element. Kinetic energy is proportional to the square of the speed, so an increase in the speed of the missile element by 10% leads to an increase in the kinetic energy of the missile element by 21%.

Known rifle complex for self-defense, containing a barrel of small arms and a cartridge, including a sleeve with a propelling charge and means of initiating it, a bullet and powder wad, characterized in that the bullet is made in the form of a spherical non-metallic element, and the diameter of the spherical element is 1.5 mm larger diameter of the bore [3].

The disadvantages of the known cartridge are the low stability of ballistic characteristics, a narrow scope and the inability to use for firing self-loading weapons, due to the presence of a hard ratio of the diameter of the missile element and the diameter of the barrel bore. Practice shows that the strict ratio of the diameter of the missile element and the diameter of the barrel bore makes it impossible to use known cartridges for firing from various models of weapons, does not ensure the stability of ballistic characteristics and excludes the possibility of using self-loading weapons for firing. The diameter of the barrel bore of a self-loading weapon designed for firing with traumatic cartridges is determined from the operating conditions of the reloading mechanisms and may significantly differ from that specified for a known cartridge. In addition, in most cases, the bore diameter of the barrel of a self-loading weapon is made variable in length. So, for example, the MP-471 traumatic service pistol, designed for firing with 10 × 23T caliber traumatic cartridges with a diameter of 10 mm throwing element, has a barrel bore diameter of 8 mm at the chamber exit and 6.5 mm at the muzzle. The indicated diameters of the bore, selected to ensure stable operation of the reloading mechanisms, differ significantly from the ratio for the known cartridge. For barrelless weapons that do not have a barrel, the parameters of a known cartridge cannot be determined at all.

Also known is a traumatic cartridge containing a sleeve, a primer, a propellant charge and several successive bullets, the centers of mass of which are located on the axis of the cartridge, characterized in that the sleeve is crimped at the front end and the smallest inner diameter of the compressed end of the sleeve is 0.90 -0.97 caliber weapons [4].

The disadvantages of the known cartridge are the low stability of ballistic characteristics and a narrow scope. Practice shows that the ratio of the diameter of the outlet of the sealed portion of the sleeve and the diameter of the bore of the barrel indicated for a known cartridge makes it impossible to use known cartridges for firing from various models of weapons, does not provide stability of ballistic characteristics and makes it difficult to use for firing from self-loading weapons. For barrelless weapons that do not have a barrel, the parameters of a known cartridge cannot be determined at all.

Indeed, fixing a missile traumatic element in the sleeve by circular deformation of the sleeve of the sleeve makes it possible to exclude the loss of the missile traumatic element from the sleeve during transportation, loading cartridges and inertial loads during firing, to stabilize the pressure of the powder gases, and to increase the completeness of combustion of the powder charge. However, the stability of ballistic characteristics can be achieved only with the optimal ratio of the inner diameter of the sleeve, the diameter of the outlet of the sealed portion of the sleeve and the diameter of the missile element, and not the ratio of the diameter of the outlet of the sealed portion of the sleeve and the diameter of the bore. In addition, the design of the known cartridge, eliminating the possibility of the missile element falling out of the sleeve, does not exclude the possibility of its movement inside the sleeve. The ability to move the missile element inside the sleeve eliminates the possibility of achieving stable ballistic characteristics of the cartridge.

Closest to the proposed cartridge is a traumatic cartridge containing a sleeve compressed at the front end, an igniter capsule, a propellant charge and a throwable body fixed inside the sleeve, characterized in that the smallest inner diameter of the compressed end of the sleeve is 0.90-0.97 caliber weapons, and the length of the compressed section of the shell case from the muzzle end is 1.8-1.9 caliber weapons [5].

The disadvantages of the known cartridge are the low stability of ballistic characteristics and a narrow scope. Practice shows that the ratio of the diameter of the outlet of the sealed portion of the sleeve and the diameter of the bore of the barrel, the length of the crimped portion of the sleeve and the diameter of the bore of the barrel indicated for a known cartridge makes it impossible to use known cartridges for firing from various models of weapons, does not provide stability of ballistic characteristics and excludes the possibility of using firing from self-loading weapons. The ratio of the length of the sleeve and the diameter of the sleeve specified for the known cartridge significantly exceeds the ratio required for the normal operation of the reloading mechanism and retrieve the spent sleeve for self-loading short-barreled weapons. A significant and unused sleeve length requires a substantial increase in the length of the gun magazine to unacceptable sizes. The sharp edge of the end of the sleeve eliminates the possibility of stable operation of the reloading mechanism when sending a cartridge into the chamber of a self-loading weapon. For barrelless weapons that do not have a barrel, the parameters of a known cartridge cannot be determined at all.

Indeed, the excess of the diameter of the missile element over the smallest inner diameter of the compressed front part of the sleeve in the known cartridge eliminates the loss of the missile traumatic element from the sleeve during transportation, loading cartridges and inertial loads during firing, stabilize the pressure of the powder gases, and increase the completeness of combustion of the powder charge. However, the stability of ballistic characteristics can be achieved only with the optimal ratio of the outer diameter of the sleeve, the inner diameter of the sleeve, the diameter of the missile element, the diameter of the outlet of the deformed portion of the barrel of the sleeve, the shape and size of the deformed portion of the barrel of the sleeve, and not the ratio of the diameter of the outlet of the sleeve and the diameter of the barrel bore and the ratio of the length of the compressed part of the sleeve and the diameter of the bore. In addition, the design of the known cartridge, eliminating the possibility of the missile element falling out of the sleeve, does not exclude the possibility of its movement inside the sleeve. The ability to move the missile element inside the sleeve eliminates the possibility of achieving stable ballistic characteristics of the cartridge.

The technical problems solved in the present invention are to increase the stability of the ballistic characteristics of traumatic cartridges and expand the scope.

These technical tasks are achieved by the fact that in a traumatic cartridge containing a rigid sleeve, an igniter capsule, a propelling charge and a spherical traumatic element made of elastic material, fixed in the sleeve by circular deformation of the sleeve barrel, the diameter of the traumatic element being thrown is 1.1-1.3 the inner diameter of the cylindrical part of the sleeve and 1.5-1.7 diameter of the outlet of the deformed part of the sleeve of the sleeve, and the deformed part of the sleeve of the sleeve is rounded with a radius of rounding, comprising 0.2-0.4 of the outer diameter of the sleeve, and the length of the deformed section of the barrel of the sleeve of the sleeve is 0.2-0.35 of the outer diameter of the sleeve.

Figure 1 shows a traumatic pistol cartridge, figure 2 shows a traumatic cartridge intended for firing from revolvers, firing devices, smooth-bore and barrelless weapons. The cartridges contain an encapsulated rigid sleeve 1, a propelling charge 2 and a missile spherical traumatic element made of elastic material 3, fixed in the sleeve by a circular deformation of the sleeve barrel.

Figure 3 shows the dimensions, the optimal ratios of which ensure the stability of ballistic characteristics and a wide range of application of cartridges: the outer diameter of the sleeve (D), the inner diameter of the sleeve (d1), the diameter of the missile traumatic element (d2), the diameter of the outlet of the deformed part of the barrel muzzle ( d3), the radius of curvature of the deformed portion of the sleeve of the sleeve (R), the length of the deformed portion of the sleeve of the sleeve (L).

The stability of the ballistic characteristics of the cartridges and the possibility of using cartridges for firing from a wide range of models of long-barreled, short-barreled, barrelless, self-loading and non-self-loading weapons are largely determined by the optimal ratio of geometric dimensions: the outer diameter of the sleeve, the inner diameter of the sleeve, the diameter of the missile element, the diameter of the outlet of the deformed part sleeve dulets, the shape and size of the deformed portion of the sleeve dule. Optimum ratios of geometric dimensions, ensuring the stability of ballistic characteristics and a wide range of cartridges, are in fairly narrow ranges. Going beyond the optimal size ratios entails a decrease in the stability of ballistic characteristics and a narrowing of the scope of the cartridges.

According to the results of the tests, the optimal diameter of the traumatic element being thrown is 1.1-1.3 of the inner diameter of the cylindrical part of the sleeve and 1.5-1.7 of the diameter of the outlet of the deformed part of the sleeve of the sleeve, the rounded shape of the deformed part of the sleeve of the sleeve with the radius of curvature is optimal constituting 0.2-0.4 of the outer diameter of the sleeve, the optimal length of the deformed section of the barrel of the sleeve of the sleeve is 0.2-0.35 of the outer diameter of the sleeve.

The optimal diameter of the missile traumatic element is 1.1-1.3 of the inner diameter of the cylindrical part of the sleeve. An increase in the diameter of the missile traumatic element at a given inner diameter of the sleeve leads to permanent deformation of the missile traumatic element, the deviation of the shape of the missile traumatic element from the spherical during storage and a significant increase in the dispersion of trajectories during firing. The tests performed show that even at a distance of 3 m from the muzzle, the deviation of the trajectory of the missile element with permanent deformation can be 0.5 m or more from the aiming point. The low stability of the trajectory of the missile traumatic element reduces the effectiveness of the traumatic weapon. Reducing the diameter of the missile traumatic element worsens the conditions for protecting the propellant charge from atmospheric factors and leads to a decrease in the stability of the pressure of the powder gases, and also makes it possible to move the missile traumatic element in the sleeve during shocks, drops, inertial loads during firing, changing the charge density and also reduce stability of pressure of powder gases.

The optimal diameter of the missile traumatic element is 1.5-1.7 of the diameter of the outlet of the deformed part of the barrel muzzle. The relationship between the diameter of the missile element and the diameter of the outlet largely determines the nature of the ballistic processes during firing, the pressure of the powder gases, the completeness of combustion of the propellant charge. A significant effect of the diameter of the outlet on the nature of the ballistic processes is mainly due to the low mass of the missile element made of elastic material, which is several times smaller than the mass of the solid missile element (bullet) of traditional small arms cartridges. The passage of a missile traumatic element through the outlet of the deformed part of the barrel of the sleeve is an analogue of forcing for traditional small arms. An increase in the diameter of the outlet at a given diameter of the missile element leads to a decrease in the pressure of the powder gases, a decrease in the completeness of combustion of the propellant charge, and a decrease in the stability of ballistic characteristics. Reducing the diameter of the outlet leads to an increase in the pressure of the powder gases, an increase in the loads on the sleeve and parts of the weapon, which absorb the greatest load during firing, increase the danger of the weapon, and entail other negative phenomena associated with increased pressure of the powder gases. It must be borne in mind that only the optimal ratio between the diameter of the projectile element and the diameter of the outlet of the deformed part of the barrel barrel can provide the necessary completeness of combustion of the propellant charge and the stability of the pressure of the powder gases. Significant resistance arising during the passage of the missile traumatic element through the outlet, provides the burning of the propellant charge at a constant volume and pressure of the powder gases necessary for the complete combustion of the propellant charge. No correlation of the diameter of the missile element and the inner diameter of the barrel channel is capable of ensuring the completeness of combustion of the propellant charge with a sharply increased volume of powder gases and a corresponding drop in their pressure.

The optimal is the rounded shape of the deformed part of the barrel of the barrel with a radius of curvature of 0.2-0.4 of the outer diameter of the sleeve. The rounded shape provides the best conditions for sending the cartridge into the chamber and stable operation of the mechanisms for reloading self-loading weapons, convenience and ease of loading non-self-loading weapons. For traumatic cartridges that do not have a protruding bullet and have an adverse relationship between the length of the cartridge and the diameter of the sleeve, the shape of the deformed part of the sleeve is crucial to ensure the stable operation of reloading mechanisms. The reduction of the radius of the rounding of the deformed part of the barrel barrel leads to the deterioration of the working conditions of the mechanisms for reloading self-loading weapons, the sticking of cartridges when reloading into the chamber, the unstable operation of the mechanism of reloading, and delays in firing. For non-self-loading weapons, a decrease in the radius of the rounding of the deformed part of the barrel barrel leads to a deterioration in the loading conditions of the weapon, which, in most cases, is carried out in a hurry, to the touch and is accompanied by stress that is inevitable when using the weapon for self-defense. The increase in the radius of curvature of the deformed part of the sleeve of the sleeve leads to an unstable position of the missile traumatic element in the sleeve. When the cartridges are equipped, deformation of a sleeve with a large radius of curvature extrudes a missile traumatic element in the direction of the bottom of the liner and prevents a stable position of the missile traumatic element in the liner in the optimal position, in which the front surface of the missile traumatic element is pressed against the inner surface of the deformed portion of the barrel muzzle.

The optimal length of the deformed section of the sleeve of the sleeve is 0.2-0.35 of the outer diameter of the sleeve. Reducing the length of the deformed section of the cartridge case barrel leads to a deterioration in the working conditions of the mechanisms for reloading self-loading weapons, sticking of cartridges when reloading into the chamber, unstable operation of the mechanisms of reloading. The increase in the length of the deformed section of the sleeve of the sleeve leads to an unstable position of the missile traumatic element in the sleeve. The deformation of the sleeve on the longer section leads to the extrusion of the missile traumatic element towards the bottom of the sleeve and prevents the stable position of the missile traumatic element in the sleeve in the optimal position, in which the front surface of the missile traumatic element is pressed against the inner surface of the deformed part of the sleeve of the sleeve.

The stability of ballistic characteristics and the wide range of applications of traumatic cartridges having an optimal ratio of geometric dimensions (outer diameter of the sleeve D, inner diameter of the sleeve d1, diameter of the missile traumatic element d2, diameter of the outlet of the deformed portion of the barrel of the sleeve d3, radius of curvature of the deformed portion of the barrel of the sleeve R, length deformed section of the sleeve of the sleeve L), is confirmed by the test results of 9-mm caliber cartridges, .380 ME Gum, 10 × 22T, 10 × 23T, 12 × 23T, 12/50 SAPL with metal with a sleeve. The dimensions for the cartridges of these calibers are given in the table.

The size Value mm 9 mm RA .380 ME Gum 10 × 22T 10 × 23T 12 × 23T 12/50 SAPL D 9.5 9.5 9.75 9.93 12.01 20,2 d1 8.5 8.5 8.75 8.9 11.00 19,4 d2 10,2 10,2 10,2 10,2 13.0 23.0 d3 6.4 6.4 6.4 6.5 8.2 14.5 R 3 3 3 3 3,5 6.0 L 2.6 2.6 2.7 2.7 3,1 5.1

When fired, the igniter capsule fires and ignites the propellant charge. Gunpowder gases generated during the combustion of a propelling charge push a traumatic missile element out of the sleeve. The optimal ratio of the geometrical dimensions of the cartridges (the outer diameter of the cartridge case, the diameter of the cartridge shell, the diameter of the outlet of the deformed part of the cartridge case, the shape and size of the deformed part of the cartridge case) determines the stability of ballistic characteristics and the possibility of using traumatic cartridges for firing from a wide range of long-barrel models , short-barreled, barrelless, self-loading and non-self-loading weapons. The stability of the ballistic characteristics of the cartridges determines the stable operation of the mechanism for reloading self-loading weapons, the convenience of loading and reloading non-self-loading weapons, and the general stability of the characteristics of the rifle complex.

INFORMATION SOURCES

1. Materials of the Permanent International Commission of the Brussels Convention on the Mutual Recognition of Test Marks for Handguns. Tables of maximum cartridge sizes and minimum cartridge sizes. Permanent International Commission for the Proof of Small-arms (C.I.P.). Tables of dimensions of cartridges and chambers. Edition 2003. English translation of the edition of the Bureau Permanent de la Comission Internationale Permanente. 45, rue Fond-des-Tawes 45, B-4000 Liege - Belgique.

2. Materials of the Permanent International Commission of the Brussels Convention on the Recognition of Test Marks of Handguns. INTERNATIONALE PERMANENTE (C.I.P.) POUR L′ÉPREUVE DES ARMES Á FEU PORTATIVES. XXVIIIéme SESSION PLÉNIÈRE VIENNE (Autriche) du 18 au 21 Septembre 2006.

3. RF patent No. 2055299. Shooting complex for self-defense.

4. RF patent No. 2103648. Cartridge.

5. RF patent No. 2103646. Cartridge.

Claims (1)

A traumatic cartridge containing a rigid sleeve, an igniter capsule, a propelling charge and a spherical traumatic element made of elastic material fixed in the sleeve by circular deformation of the sleeve barrel, characterized in that the traumatic element is made with a diameter equal to 1.1-1.3 of the inner diameter the cylindrical part of the sleeve and the 1.5-1.7 diameter of the outlet of the deformed part of the barrel of the sleeve, which is rounded with a radius of curvature of 0.2-0.4 of the outer diameter of the sleeve, the length of the deformed part of the barrel muzzle is 0.2-0.35 of the outer diameter of the sleeve.

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