RU186077U1 - MULTI-CUTTER FOR RUNNING WEAPONS WITH A CALIBER MORE THAN 7.62 mm - Google Patents

Abstract

The utility model relates to bullet catchers working in closed shooting ranges when using small arms with a caliber of more than 7.62 mm and under conditions of increased dynamic load (firing in bursts). The bullet collector includes a lower bullet reflector and an upper bullet reflector placed obliquely towards the neck of the bullet chamber, consisting of armored steel sheets with a hardness of 440-480 HB according to Brinell, and a bullet collector. The thickness of the armored steel sheets of the reflectors is not less than 20 mm, the reflectors are located at an angle to the horizontal surface lower from 15 to 20, and the upper from 16 to 20 degrees. The thickness of the armored steel sheets of the neck of the bullet chamber is made at least 20 mm. The bulletproof chamber is a continuation of the upper bullet reflector and has longitudinal grooves in its lowermost part, and the bullet collector is placed under the longitudinal grooves of the bulletproof chamber. The mathematical dependence of calculating the angle of the bullet reflector and the thickness is proposed. The claimed technical solution allows to increase the dynamic strength of the bullet catcher, reduce wear on the surface of the lower and upper bullet deflectors, the neck of the bullet chamber, increase the life of the bullet catcher, eliminate the undefined ricochet of bullets and their fragments towards the arrow, simplify the installation of the bullet catcher. 3 s.p. f-ly, 1 ill.

Description

The utility model relates to bullet catchers working in closed ranges when using small arms with a caliber of more than 7.62 mm and in conditions of increased dynamic load (firing in bursts).

The utility model can be used to ensure the safety of firing by eliminating the indeterminate ricochet of bullets or their fragments towards the shooter, the absence of destruction of the bullet catcher during factory tests of weapons with a heat-strengthened core and when shooting experimental weapons, including when firing bursts. The claimed technical solution is used as elements of armored anti-ricochet protection in shooting galleries under conditions of increased dynamic load compared to the load that is regulated by GOST R 52212-2004, when firing bursts and ammunition of large caliber with a heat-strengthened core, and provides increased reliability and durability of the structure.

A bullet collector comprising an upper bullet reflector, a lower bullet reflector, a bullet chamber with a reflecting element and a container for collecting and removing bullets is known from the prior art (see US Pat. No. 5,657,575, F41J 13/00, 1987). The lower bullet reflector is mounted on the inclined frame elements, the upper bullet reflector is placed at an angle to the side of the container for collecting and removing bullets and a bullet chamber. Bullet reflectors are made of armored steel sheets.

A prototype of the proposed technical solution is a bullet collector, including a lower bullet reflector and an upper bullet reflector, placed at an angle to the neck of the bullet-receiving chamber, consisting of armored steel sheets, and a bullet collector (see RF patent 2367886, F41J 13/00, 2009). When a bullet hits a curved lower bullet reflector, it is reflected and can fall into the upper bullet reflector and then into the bullet chamber or directly into the bullet chamber. In a bulletproof chamber, a bullet moves by inertia, making circular movements, and then rolls into a bullet collector. The hardness of armored steel sheets can be more than 400 HB according to Brinell. Bulletproof chamber has a wall thickness of 1.0-3.0 caliber used weapons. The upper reflector is located at an angle to a horizontal surface of up to 15 degrees.

The disadvantage of both the analogue and the prototype is that their design does not provide for shooting in the shooting range with modern small arms cartridges with a caliber of more than 7.62 mm, which have bullets with solid heat-strengthened cores. Used bullets with such cores often exceed the hardness of the materials from which the elements of the bullet collector are made. Not only modern, but also new types of bullets with increased dynamic load lead to accelerated wear of the lower bullet reflector, the upper bullet reflector and the neck of the bullet chamber. The durability of armored steel sheets is reduced. As the armor plates of the upper and lower bullet reflectors wear out, their geometry changes, mass removal occurs on the surface in places of active contact with the bullets, recesses appear, that is, there is a possibility of an undefined rebound towards the firing line. Insufficiently shallow angle of inclination of the bullet reflectors does not provide a stable direction of movement of the bullet towards the bullet chamber. A bullet rebound may occur, especially with a lead core. Also, the value of the actual barrier of the bullet of the steel armor plate is insufficient

bullet reflectors. In addition, the use of the formula 1.0-3.0 caliber of the used weapon to select the wall thickness of the bullet-receiving chamber leads to unreasonably large weight, and therefore the installation of the bullet collector is complicated and time-consuming, and the constructive implementation of the transition of the bullet reflectors to the bullet collector and the withdrawal of bullets from it lengthens the way they get into the bullet collector.

The task this utility model is aimed at is to increase the level of security of bullet shooting in a closed shooting range and to comply with the requirements of GOST R 52212-2004 for technical strength, armor protection in closed shooting galleries and Brinell hardness of armored steel sheets. The objective is also to eliminate the indefinite ricochet of bullets or their fragments towards the shooter when firing at close range from three to five meters. In addition, the tasks that this utility model is aimed at should include an increase in reliability, an increase in durability, an increase in the actual obstacle of a bullet of a steel armor plate of bullet deflectors, a simplification of the design, a decrease in the complexity of assembly and an improvement in shooting conditions.

The technical result in the implementation of the proposed utility model is to reduce the wear of the front surface of the lower reflector, upper reflector, bullet chamber and, as a result, increase the service life of the collector. A steady direction of the bullet’s movement towards the bullet-receiving chamber is ensured by choosing the angle of inclination of the bullet reflectors and reducing their wear, installation of the bullet catcher is simplified, and labor intensity is reduced. The technical result should also include the fact that the bullets hit the bullet box along a shortened path - through the groove in the bullet-receiving chamber, the bullets do not have the ability to change the direction of their movement when they fall into the lower bullet reflector during shooting, indefinite ricochet of bullets and their fragments to the side is excluded arrow, increasing the level of safety of shooting.

The following essential features influence the achievement of the indicated technical result. In a bullet catcher for small arms with a caliber of more than 7.62 mm, which includes a lower bullet reflector and an upper bullet deflector placed obliquely towards the neck of the bulletproof chamber, consisting of armored steel sheets with a hardness of 440-480 HB according to Brinell, and a bullet collector, the thickness of armored steel sheets bullet reflectors are made not less than 20 mm, and bullet reflectors are located at an angle to the horizontal surface lower from 15 to 20 degrees and upper from 16 to 20 degrees. The thickness of the armored steel sheets in the neck of the bullet chamber is made at least 20 mm. The bulletproof chamber is a continuation of the upper bullet reflector and has longitudinal grooves in its lowermost part, and the bullet collector is placed under the longitudinal grooves of the bulletproof chamber. The actual value of the bullet barrier in the lower and upper reflectors is determined by the equation:

Bf = B⋅ctqα

where Vf is the actual value of the thickness of the barrier of the steel armor plate of the bullet reflector;

B is the thickness of the steel armor plate of the bullet reflector;

ctqα is the cotangent of the angle α of the inclination of the bullet reflector.

Distinctive features of the claimed technical solution from the prototype is that in the bullet catcher for small arms with a caliber of more than 7.62 mm, the thickness of the armored steel sheets of the bullet reflectors is not less than 20 mm, and the bullet reflectors are located at an angle to the horizontal surface lower from 15 to 20 degrees and upper from 16 to 20 degrees. The thickness of the armored steel sheets in the neck of the bullet chamber is made at least 20 mm. The bullet-receiving chamber is a continuation of the upper bullet reflector and has longitudinal grooves in its lowermost part, and the bullet collector is placed under the longitudinal grooves of the bullet-receiving chamber. The actual value of the bullet barrier in the lower and upper reflectors is determined by the equation:

Bf = B⋅ctqα

where Vf is the actual value of the thickness of the barrier of the steel armor plate of the bullet reflector;

B is the thickness of the steel armor plate of the bullet reflector;

ctqα is the cotangent of the angle α of the inclination of the bullet reflector.

Through the use of armored steel sheets of bullet reflectors with a thickness of at least 20 mm, their dynamic strength is increased, the destruction of the bullet collector during operation is reduced, and the durability and safety of the shooting gallery are increased. Due to the implementation of bullet reflectors to the horizontal surface of the lower one at an angle of 15 to 20 degrees and the upper one at an angle of 16 to 20 degrees, the dynamic load on the catcher is reduced. The weight loss of the armored steel sheets during the interaction of the bullet with the bullet deflectors is reduced, the wear of their surfaces is reduced, the direction of movement of bullets and their fragments towards the bulletproof camera is increased, the likelihood of a rebound towards the shooter is eliminated, and the shooting safety is increased. In addition, when shooting in bursts, it is advisable to place the upper bullet reflector at an angle of 16 to 20 degrees to the horizontal surface and the lower one at an angle of 15 to 20 degrees to the horizontal surface, while the location of the bullet reflectors at these angles significantly reduces their wear when firing bullets with hard cores and eliminates the ricochet towards the shooter when firing bullets with lead cores. The thickness of the armored steel sheets of the bulletproof chamber of at least 20 mm ensures uniform wear of all structural elements with which they interact when firing a bullet. The design is simplified, assembly is less time consuming. The grooves make it possible to hit bullets directly into the bullet collector, which simplifies the design. Calculation of the actual value of the bullet barrier in the lower and upper bullet reflectors allows you to optimize the design of the bullet catcher for a specific shooting range project, allows you to take into account the length of the shooting range when choosing the angle of inclination of the bullet reflector,

the thickness of the required armored steel sheets for the nomenclature of the tested weapons and the type of test.

The essence of the utility model is illustrated by graphic material.

In FIG. 1 is a schematic side view of a bullet collector.

The bullet catcher for small arms with a caliber of more than 7.62 mm includes a lower bullet reflector 1, an upper bullet reflector 2, a bullet chamber 3 with a neck 4 and longitudinal grooves 5, and a bullet collector 6. The lower bullet reflector 1 is placed on the inclined frame elements (not shown in the drawing ) The bullet collector at the top is limited by the upper bullet reflector 2. The lower bullet reflector 1 and the upper bullet reflector 2 are placed at an angle to the neck 4 of the bullet chamber 5 above a horizontal surface. Bullet reflectors 1 and 2, when approaching each other, form the neck 4 of the bullet-receiving chamber 5, which is located in the direction of the axis of fire and is cylindrical. The lower bullet reflector 1, the upper bullet reflector 2, the bulletproof chamber 3 and the neck 4 are made of armored steel sheets. Bullet reflectors 1 and 2 are made of armored steel sheets with a thickness of at least 20 mm. The lower bullet reflector 1 is located at an angle of 15 to 20 degrees to the horizontal surface (the drawing shows the angle α of the lower bullet reflector). The upper reflector 2 is located at an angle of 16 to 20 degrees to the horizontal surface (the drawing shows the angle α of the upper reflector). Armored steel sheets should have a hardness of 440-480 HB Brinell.

In the embodiment, the bullet chamber 3 is a continuation of the upper bullet reflector 4 and has longitudinal grooves 5 in its extreme lower part along the neck 4 of the bullet chamber 3 below it. The bullet box 6 is placed under the longitudinal grooves 5 of the bullet chamber 3. The thickness of the armored steel sheets of the neck 4 of the bullet chamber 3 must be at least 20 mm. The cylindrical bulletproof chamber 3 passes into the upper bullet reflector 2, its cylindrical surface is docked from below

lower reflector 1 and forms a closed direction of movement of the bullet by inertia. Made in the cylindrical surface under the neck 4 of the bullet-receiving chamber 3, the longitudinal grooves 5 provide further movement of bullets down to the bullet box 6.

Bullet catcher for small arms with a caliber of more than 7.62 mm works as follows.

The shooter in the shooting range carries out aimed shooting along the axis of fire towards the target, which is located in front of the bullet catcher. Bullets are directed towards the neck 4 of the bullet-receiving chamber 5 and can fall into the lower bullet reflector 1 or into the upper bullet reflector 2 of the bullet collector. Bullets fall into the lower bullet reflector at least 20 mm thick located at an angle of 15 to 20 degrees to the horizontal surface or bullets fall into the upper bullet reflector with a thickness of at least 20 mm located at an angle of 16 to 20 degrees to the horizontal surface. The bullet collector can take increased dynamic loads compared to the load regulated by GOST R 52212-2004, - firing bursts and ammunition of large caliber with heat-strengthened cores. This is due to the fact that when a bullet comes in contact with the axis of the lower bullet reflector 1 at an angle of 15 to 20 degrees to the horizontal surface, a steel armor sheet with a thickness of "B" equal to 20 mm or more has an actual barrier thickness several times greater than armor plate thickness. And she makes up

Bf = B⋅ctqα;

where: Vf is the actual value of the thickness of the barrier of the steel armor plate of the bullet reflector;

B is the thickness of the steel armor plate of the bullet reflector;

ctqα is the cotangent of the angle α of the inclination of the bullet reflector.

For example, if the angle “α” is 15 degrees, ctqα is 3.723. And with an angle of α, 20 degrees, ctqα is 2.747. That is, the actual value of the thickness of the barrier of the steel armor plate, both lower and upper

bullet reflectors increases significantly. The experimental data when using large-caliber ammunition with heat-strengthened cores and when firing bursts suggest that these angle values are optimal for closed shooting galleries, and the thickness of the sheet used cannot be less than that specified for the standard material. You can choose the thickness of the steel armor plate in the case of obtaining technical specifications for the manufacture of a shooting gallery using specific munitions in it. For example, for a caliber of 7.62, the thickness of the steel armor plate is chosen equal to 12 mm. For the cases specified in the standard, that is, when using large-caliber ammunition and firing in bursts, it is possible to calculate the thickness of the steel armor plate based on ensuring the necessary bullet resistance and durability. From ballistic calculations it is known that if the ratio of the actual thickness of the metal of the armor plate to the caliber of the bullet increases, then the protective properties and the performance of the structure increase. Guided by the bullet caliber data in the technical task, it is possible to determine the necessary actual thickness (Vf) of the metal of the armor plate determined from the relation Bf = В⋅ctqα. The obtained values of Vf allow you to choose the thickness of the armor plate and the angle of inclination of the bullet reflectors. Further, moving along the axis of fire, the bullets fall into the neck 4 of the cylindrical bulletproof chamber 3, which is a continuation of the upper bullet reflector 4, and move inside the chamber 3 along its cylindrical surface until it stops. Then, rolling down, the bullets move to the lowermost part of the bullet chamber 3 and fall into the longitudinal grooves located under the neck 4. Then, from the longitudinal grooves 5, the bullets fall into the bullet box 6 located under the longitudinal grooves 5 of the bullet chamber 3.

Thus, the claimed technical solution allows to increase the dynamic strength of the bullet trap, reduce wear on the surface of the lower and upper bullet deflectors, the neck of the bullet chamber, increase the life of the bullet trap, and eliminate an undefined rebound

bullets and their fragments in the direction of the shooter. The assembly and assembly of the bullet collector is simplified, the complexity is reduced. In addition, it ensures compliance with the requirements for armor protection in closed shooting ranges when firing at close range, increasing the safety of shooting. The claimed technical solution provides a stable direction of movement of the bullet in the direction of the bullet-receiving chamber, it becomes possible to calculate the thickness of the lower and upper bullet reflectors and determine the angles of their inclination.

Claims (8)

1. Bullet catcher for small arms with a caliber of more than 7.62 mm, including a lower bullet reflector and an upper bullet deflector placed obliquely towards the neck of the bullet chamber, consisting of armored steel sheets with a hardness of 440-480 HB according to Brinell, and a bullet collector, characterized in that the thickness of the armored steel sheets of the reflectors is not less than 20 mm, and the reflectors are located at an angle to the horizontal surface lower from 15 to 20 degrees and the upper from 16 to 20 degrees. 2. The bullet catcher according to claim 1, characterized in that the thickness of the armored steel sheets in the neck of the bullet chamber is at least 20 mm. 3. The bullet catcher according to claim 1, characterized in that the bullet chamber is a continuation of the upper bullet reflector and has longitudinal grooves in its extreme lower part, and the bullet collector is placed under the longitudinal grooves of the bullet chamber. 4. The bullet catcher according to claim 1, characterized in that the actual value of the bullet barrier in the lower and upper bullet reflectors is determined by the equation: Bf = B⋅ctqα, where Vf is the actual value of the thickness of the barrier of the steel armor plate of the bullet reflector; B is the thickness of the steel armor plate of the bullet reflector; ctqα is the cotangent of the angle α of the inclination of the bullet reflector.

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