RU2287765C1 - Bullet catcher - Google Patents

Abstract

FIELD: devices for catching of bullets and fragmentation shells, in particular, bullet catchers.

SUBSTANCE: the bullet catcher has at least one module containing two vertical bullet reflectors located on the opposite sides of the firing axis, and a chamber connected to them with formation of a neck. The first of the bullet reflectors is made in the form of a high-strength steel sheet inclined at angle α to the firing axis, and the second of them is made in the form of two adjacent high-strength steel sheets, one of which is inclined at angle β to the firing axis, and the other adjoining the chamber is positioned in parallel with the firing axis or deflected from it. The connecting line of the two adjacent high-strength steel sheets of the second bullet deflector lies in the plane passing through the front edge of the first bullet deflector and forming with it angle γ, and angles α, β and γ are selected from the condition of prevention of the reverse ricochet of bullets and/or their fragments.

EFFECT: enhanced survivability in the conditions of multiple impact load.

12 cl, 3 dwg

Description

The invention relates to devices for conducting training and sports shooting and weapon testing, and in particular to devices for trapping bullets and shotguns when firing from small arms and controlling their discharges.

In any shooting range, the main load during firing is tested by a bullet collector, and its functioning largely determines the operational capabilities of a particular shooting range. The choice of a rational design of the bullet collector allows to reduce the volume of construction and installation works, which is especially important for closed shooting ranges, which, as a rule, are quite expensive capital structures, as well as to increase the life of the shooting gallery while ensuring the safety of firing.

Known bullet collector, which includes several interconnected modules, each of which contains two vertical flat bullet reflectors, converging on opposite sides of the axis of fire to the camera, connected to these bullets with the formation of the neck (US 5088741, F 41 J 1/12, 1992) . This design of the bullet catcher allows you to use it for a mobile shooting gallery of a closed type.

Currently, when firing in closed ranges, modern small arms cartridges are used that have bullets with heat-strengthened or carbide cores. In this case, the hardness of the cores of these bullets often exceeds the hardness of the materials used in the designs of bullet collectors, in particular for the manufacture of such elements of the bullet collector as bullet reflectors. As you know, the survivability of the bullet reflector increases with a decrease in the angle of meeting of the bullet and the bullet reflector. However, the use of bullet reflectors with small meeting angles in practice leads to an excessive increase in the linear dimensions of the bullet collector and, as a result, an increase in the length of the shooting range.

The objective of the present invention is to provide a bullet catcher with increased survivability under conditions of multiple shock loading of its elements and increased braking efficiency of the bullet and ensuring the exclusion of reverse rebound, i.e. emissions of a bullet and / or its fragments in the direction of the firing, when using such a bullet catcher in a stationary or mobile shooting range.

The solution to this problem is a bullet collector, comprising at least one module containing two essentially vertical bullet deflectors located on opposite sides of the firing axis, a camera connected to these bullet deflectors with the formation of a neck, while the first of these bullet deflectors is made in the form of high-strength steel a sheet inclined at an angle α to the axis of fire, and the second of these bullet deflectors is made in the form of two adjacent high-strength steel sheets, one of which is inclined along d angle β to the axis of fire, and the other adjacent to the camera is parallel to the axis of fire or deviated from it, while the connection line of two adjacent high-strength steel sheets of the second bullet reflector lies in a plane passing through the front edge of the first bullet reflector and forming an angle γ , and the angles α, β, and γ are selected from the condition for preventing reverse rebound of bullets and / or fragments thereof.

The angle α can be determined by the formula:

where HD _in is the dynamic hardness of the material of the first bullet reflector;

HD _cn - dynamic hardness of the bullet core material;

ρ _SP - the density of the material of the core of the bullet;

V is the speed of the bullet at the time of impact;

the angle β does not exceed the angle α.

Preferably, the angle α varies in the range of 20-45 °, and the angle β varies in the range of 0-45 °.

The angle γ is preferably 0.2-0.7 α.

More preferably, the angle γ is 0.3-0.6 α.

When firing bullets with heat-strengthened cores, the angle β can be determined by the formula:

The second bullet reflector may have an additional reflective element located in the neck of the camera.

The camera can be made in the form of a segment of the pipe and connected to the first bullet reflector tangentially.

Preferably, such a chamber has a diameter of (20-50) d and a wall thickness of (1.0-3.0) d, where d is the caliber of the weapon.

The first bullet reflector can be connected to the camera through an intermediate flat bullet reflector, while the intermediate flat bullet reflector is made of material whose strength is not lower than the strength of the material of the first bullet reflector.

The first and second bullet reflectors are preferably made of material with a hardness HB not lower than 400 units.

Bullet collector contains means for connecting modules.

The essence of the catcher is shown in the drawings:

figure 1 shows a General view of the bullet reflector containing several modules;

figure 2 is a cross section of a module with a camera having a cylindrical wall;

figure 3 is a cross section of a module with a camera connected by an intermediate flat reflector with the first reflector.

Bullet reflector 1 contains one or more modules 2, which can be mounted on a frame (not shown). Each module 2 contains a substantially vertical first bullet reflector 3 and a second bullet reflector 4 connected to the chamber 5 with the formation of the neck 6. The chamber 5 is designed to capture bullets and their fragments. In the lower open part of the chamber 5 there is a container for collecting and removing bullets and their fragments (not shown).

Bullet reflectors 3 and 4 are located on opposite sides of the axis of fire. The bullet reflector 3 is made in the form of a high-strength steel sheet 7, inclined at an angle α to the axis of fire.

The angle α when firing bullets with solid cores is determined by the formula:

where HD _in is the dynamic hardness of the material of the first bullet reflector;

HD _cn - dynamic hardness of the bullet core material;

ρ _SP - the density of the material of the core of the bullet;

V - bullet speed at the moment of impact.

With this value of the angle α, the conditions for the appearance of a reverse rebound are practically excluded even when the surface of the reflectors 3 and 4 is deformed, which arises from their impact interaction with bullets having solid cores.

The bullet reflector 4 is made in the form of two adjacent high-strength steel sheets 8 and 9 having a connection line 10. In this case, the high-strength steel sheet 8 is inclined at an angle β to the firing axis, and the high-strength steel sheet 9 adjacent to the camera 5 can be parallel to the firing axis or deviated from it, i.e. the angle of inclination of the high strength steel sheet 8 to the axis of fire is positive, and the angle of inclination of the high strength steel sheet 9 to the axis of fire is either zero or negative.

The angle β preferably does not exceed the angle α, which also helps to prevent reverse bounce.

The preferred range for the angle α is 20–45 °, and the angle β is 0–45 °.

The connection line 10 of high-strength steel sheets 8 and 9 lies in a plane passing through the leading edge 11 of the bullet reflector 3, and forms an angle γ with a high-strength steel sheet 7 of the bullet reflector 3, equal to 0.2-0.7 α., Which corresponds to the point of ultimate secondary collision bullets i.e. collisions of a bullet that first hit the front edge of the bullet reflector 3, and then into the bullet reflector 4. This allows you to almost halve the angle between the bullet reflectors 3 and 4, inside which ricochets of bullets or their fragments occur after a secondary collision. Similar conditions for secondary ricochets will occur when a bullet hits the area adjacent to the front edge 12 of the high-strength steel sheet 8 of the bullet reflector 4.

The angle γ is preferably 0.3-0.6 α.

In addition, when using cartridges with bullets having heat-strengthened cores, the angle β can be determined by the formula:

The above relationship of the geometric and strength parameters of the elements of the catcher 1 provide the catcher according to the present invention high survivability by reducing the wear of the surface of the bullet reflectors 3 and 4.

Bullet reflector 4 may have an additional reflecting element 13 located in the neck 6 of the chamber 5, to reduce the likelihood of bullets or fragments from the chamber 5.

For the same purpose, the chamber 5 is made in the form of a pipe segment and is connected tangentially with the bullet reflector 3. Increasing the strength of the chamber 5 is facilitated by its diameter (20-50) d and wall thickness (1.0-3.0) d, where d is the caliber of the weapon.

To increase the survivability of the bullet trap 1, the bullet reflector 3 is connected to the chamber 5 through an intermediate flat bullet reflector 14, which is made of material with a strength not lower than the strength of the material of the bullet reflector 3.

Bullet reflectors 3 and 4 are preferably made of a material with a HB hardness of at least 400 units, for example, heat-treated steel type 30HGSA.

In the case of using a bullet catcher 1 with several modules 2, these modules are mounted on a frame (not shown) and are interconnected by welding.

When firing, the bullets fall into the high-strength steel sheets 7, 8 and 9 of the reflectors 3 and 4, which deflect the bullets towards the camera 5 for trapping, i.e. the selected angles of inclination of these sheets provide a ricochet of bullets and / or fragments thereof in the direction of the camera 5 and prevent reverse bounce (bullets flying out of the catcher). During impact interaction with high-strength sheets 7, 8 and 9, bullets lose their kinetic energy, are deformed and / or destroyed, and are already in this state are captured in chamber 5 for final braking and collecting bullet fragments.

The operability of the design is confirmed by the positive results of field tests using various small arms systems.

Claims (12)

1. Bullet collector comprising at least one module containing two bullet deflectors located on opposite sides of the firing axis essentially vertically, and a chamber connected to them to form a neck, characterized in that the first bullet deflector is made in the form of a high-strength steel sheet, inclined at an angle α to the axis of fire, and the second is made in the form of two adjacent high-strength steel sheets, one of which is inclined at an angle β to the axis of fire, and the other adjacent to the camera is parallel to the axis of fire would be or deviated from it, and the line of their connection is located in a plane passing through the front edge of the first bullet reflector and forming an angle γ with it, while the angles α, β and γ are selected from the condition of preventing backward rebound of bullets and / or fragments thereof, and the angle α is determined by the formula:

where HD _in is the dynamic hardness of the material of the first bullet reflector; HD _cn - dynamic hardness of the bullet core material; ρ _SP - the density of the material of the core of the bullet; V - bullet speed at the moment of impact. 2. The bullet catcher according to claim 1, characterized in that the angle β does not exceed the angle α. 3. The bullet catcher according to claim 1, characterized in that the angle α varies in the range of 20 - 45 °, and the angle β varies in the range of up to 45 °. 4. The bullet catcher according to claim 3, characterized in that the angle γ is equal to (0.2 ÷ 0.7) α. 5. The bullet catcher according to claim 4, characterized in that the angle γ is preferably equal to (0.3 ÷ 0.6) α. 6. The bullet catcher according to claim 1, characterized in that the angle β is determined by the formula:

7. Bullet collector according to claim 1, characterized in that the second bullet reflector has an additional reflective element located in the neck of the chamber. 8. The bullet catcher according to claim 1, characterized in that the camera is made in the form of a segment of the pipe and is connected tangentially with the first bullet reflector. 9. The bullet catcher according to claim 8, characterized in that the camera has a diameter (20 ÷ 50) d and a wall thickness (1,0 ÷ 3,0) d, where d is the caliber of the weapon. 10. The bullet catcher according to claim 1, characterized in that the first bullet reflector is connected to the camera through an intermediate flat bullet reflector, while the intermediate flat bullet reflector is made of material whose strength is not lower than the material strength of the first bullet reflector. 11. Bullet collector according to claim 1, characterized in that the first and second bullet reflectors are made of material with a hardness HB not lower than 400 units. 12. The bullet catcher according to claim 1, characterized in that it comprises means for connecting the modules.

Images