RU75237U1 - MULTI-COOLER - Google Patents

Abstract

The utility model relates to devices for trapping bullets and shotguns, namely, to bullet collectors. When firing bullets / or fragments thereof, ricochet from high-strength steel sheets of the lower and upper bullet deflectors 2 and 5, as well as the reflecting element 9 inside the bulletproof chamber 6, where they are caught for final braking and collection. The inclination angles of the bullet deflectors 2 and 5 and the reflecting element 9 are selected from the condition of preventing reverse rebound of bullets and / or their fragments.

Description

The utility model relates to devices for conducting training sports and combat firing, as well as for testing weapons, namely, devices for trapping bullets and shotguns when firing from small arms.

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 main danger when shooting at the shooting range is the vague rebound of bullets or their fragments towards the shooter. The main reason for the occurrence of an undefined rebound is the joining places of the parts forming the bullet catcher, and protruding fasteners on the surface of the bullet reflectors and the bullet catcher. Ensuring the safety of firing, especially at close range, is largely determined by the design of the bullet catcher.

The choice of a rational design of the bullet collector allows to reduce the volume of installation and assembly work, which is especially important for closed-type shooting galleries, which, as a rule, are quite expensive, capital structures, and also increase the life of the shooting gallery as a whole.

Known bullet traps including an upper bullet reflector, a lower bullet reflector connected to the neck of the bullet chamber (US 3404887, F41J 1/12, 1968; US 3701532, F41J 1/12, 1972; US 5655775, F41J 1/12, 1997). The lower bullet reflector of these bullet catchers is formed by several rows of overlapped sheets in the direction of fire. This design of the bullet catcher retains the ability to ricochet back bullet fragments when they fall into the junction of the sheets. In addition, lead dust and fragments of destroyed bullets will accumulate in the joints, which complicates the maintenance of the bullet collector.

Currently, when firing in closed ranges, modern small arms cartridges are used that have solid-core bullets. Moreover, 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. It is known that the survivability of the bullet reflector increases with a decrease in the angle of the bullet and the bullet reflector. However, the use of low-angle bullet reflectors in practice

leads to an excessive increase in the linear dimensions of the bullet collector and, as a consequence, requires an increase in the length of the shooting gallery.

The objective of this utility model is to create a bullet catcher with increased survivability under conditions of multiple shock-pulse loading and the effective organization of the process of braking a bullet, eliminating the reverse rebound, i.e. ejection of a bullet or its fragments in the direction of the shooter.

The solution to this problem is a bullet collector containing an upper bullet reflector with a front surface, a lower bullet reflector with a front surface, a reflecting element adjacent to the upper bullet reflector, and a bullet-receiving chamber with a neck, one side is formed by a reflecting element, and the other side is the upper part of the lower bullet reflector, while the front surface of the lower bullet reflector is made with a profile in the form of a curve described by the equation

where R is the current radius vector (m);

φ is the angle of the current radius vector (rad);

R _o is the specified base radius vector (m) for the angle φ = 0 corresponding to the horizontal position of the weapon barrel at a given height h ₀ above the shooting gallery floor;

α is the angle of meeting of the bullet with the front surface of the lower bullet deflector, selected from the condition of preventing reverse rebound of bullets and / or their fragments and not exceeding 45 °,

or with a profile in the form of an inscribed broken line approximating the specified curved line, and the broken line contains at least three segments.

If the bullets contain solid cores, the angle α is determined by the formula

where HD _in - the dynamic hardness of the material of the lower bullet reflector (N / m ² );

HD _cn - dynamic hardness of the material of the core of the bullet (N / m ² );

ρ _SP - the density of the material of the core of the bullet (kg / m ³ );

V - bullet speed at the moment of impact (m / s).

The upper bullet catcher reflector is located with the angle of inclination of its front surface to the horizontal plane equal to 0 ° -15 °.

The height of the lower bullet reflector is (0.7-0.9) the height of the shooting range.

The reflecting element is located at an angle β = (0.75-1.0) β _* to the horizontal, while

where β _* is the angle of the tangent at the upper point of the lower bullet reflector to the horizontal;

φ _* is the angle of the radius vector at the upper point of the lower bullet reflector.

The bullet-receiving chamber is made with a wall thickness (1.0-3.0) d, where d is the caliber of the weapon (m).

Bullet-receiving chamber can be made in the form of cylindrical segments or polyhedral segments inscribed in them.

The radius of the cylindrical segments of the bullet chamber is preferably (25-50) d.

The width of the horizontal entrance to the neck of the bullet chamber is 0.150-0.450 m.

The upper and lower bullet reflectors, the reflecting element and the bulletproof chamber are made of material with a Brinell hardness of at least 400 units.

The essence of the catcher is shown in the accompanying drawings.

In Fig.1 - shows a bullet collector in section according to the present invention;

figure 2 is another example of a bullet catcher in section according to the present invention;

figure 3 is a curve describing the profile of the front surface of the lower bullet reflector;

figure 4 is a General view of the bullet catcher (frame, fasteners and bullet collectors are not conventionally shown).

The bullet collector 1 contains an upper bullet reflector 2 mounted on independent supports 3, and a lower bullet reflector 5 and a bullet chamber 6 with bullet collectors 7 equipped with containers 8 for collecting and removing bullets and their fragments mounted on the spatial frame 4. Bulletproof chamber 6 has a neck, one side of which is formed by a reflecting element 9 adjacent to the upper bulletproof 2, and the other side is the upper part of the lower bulletproof 5.

As shown in figures 1, 3 and 4, the front surface of the lower bullet reflector 5 has a profile in the form of a curve described by the equation

where R is the current radius vector (m);

φ is the angle of the current radius vector (rad);

R _o is the specified base radius vector (m) for the angle φ = 0 corresponding to the horizontal position of the weapon barrel at a given height h ₀ above the shooting gallery floor;

α is the angle of meeting of the bullet with the front surface of the lower bullet reflector, selected from the condition of preventing reverse rebound of bullets and / or their fragments and not exceeding 45 °.

This shape of the front surface of the lower bullet deflector 5 (Fig. 3) not only prevents the backward rebound of bullets and / or their fragments, but also provides the conditions of equal loading when the bullet collides with any point of the lower bullet deflector 5, which increases the survivability of the bullet trap 1.

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

where HD _in - the dynamic hardness of the material of the main bullet reflector (N / m ² );

HD _cn - dynamic hardness of the material of the core of the bullet (N / m ² );

ρ _SP - the density of the material of the core of the bullet (kg / m ³ );

V - bullet speed at the moment of impact (m / s).

With this value of the angle α, the conditions for the appearance of a reverse ricochet during impact interaction of bullets having solid cores with the front surface of the lower bullet reflector 5 are practically eliminated and its minimal wear is ensured.

To simplify the design of the lower bullet reflector 5, the curve describing the profile of its front surface can be approximated by the inscribed broken line containing at least three segments (figure 2).

In both cases, the lower bullet reflector 5 is made of high strength steel sheets joined by butt welding from the back surface of the lower bullet reflector 5.

The height of the lower bullet reflector 5 is 0.7-0.9 of the height of the shooting range, in this case more than 90% of the hits fall on the lower bullet reflector 5, and the bullets or their fragments fall into the bullet chamber 6 immediately after the first rebound.

The upper bullet reflector 2, also made of high-strength steel sheet or high-strength steel sheets connected by butt welding, has a slope of its front surface to a horizontal plane of 0 ° -15 ° for

prevent the reverse rebound of bullets or their fragments after a secondary collision with the lower bullet reflector. The reflecting element 9 directs the bullets ricocheting from the lower bullet reflector 5 into the bullet-receiving chamber 6. For this, the reflecting element 9 is installed at an angle β = (0.75-1.0) β _* . The angle β _{* is} determined by the tangent at the upper point of the lower bullet reflector 5 to the horizontal.

where φ _* is the angle of the radius vector at the upper point of the lower bullet reflector.

The horizontal entrance width “A” into the neck of the bullet-receiving chamber 6 is selected from the condition that the trajectory of the bullet rebound from the lower edge of the lower bullet reflector 5 will pass into the bullet-chamber 6, bypassing the upper bullet reflector 2 and is 0.150-0.450 m. To increase the strength of the bullet-proof chamber 6 made with a wall thickness of (1.0-3.0) d, where d is the caliber of the weapon (m).

Bulletproof chamber 6 is made in the form of cylindrical segments (10, figure 1) or polyhedral segments inscribed in them (11, figure 2).

The radius of the cylindrical segment 10 is preferably equal to (25-50) d, which helps to increase the strength of the bullet chamber 6.

The upper 2 and lower bullet reflectors 5, the reflecting element 9 and the bulletproof chamber 6 are made of material with a Brinell hardness of at least 400 units, for example, heat-treated steel of the 30KhGSA type.

In the proposed design, all elements of the bullet catcher 1 are mounted end-to-end, which virtually eliminates the reasons leading to an undefined rebound.

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

Claims (10)

1. A catcher containing an upper bullet reflector with a front surface, a lower bullet reflector with a front surface, a reflecting element adjacent to the upper bullet reflector, and a bullet-receiving chamber with a neck, one side of which is formed by a reflecting element, and the other side is the upper part of the lower bullet reflector, while the front the surface of the lower reflector is made with a profile in the form of a curve described by the equation

, where R is the current radius vector (m); φ is the angle of the current radius vector (rad); R _about - a given base radius vector (m) for the angle φ = 0, corresponding to the horizontal position of the gun barrel at a given height h ₀ above the shooting gallery floor; α is the angle of meeting of the bullet with the front surface of the lower bullet deflector, selected from the condition of preventing reverse rebound of bullets and / or their fragments and not exceeding 45 °, or with a profile in the form of an inscribed broken line approximating the specified curved line, and the broken line contains at least three segments. 2. The bullet catcher according to claim 1, in which, if the bullets contain solid cores, the angle α is determined by the formula

, where HD _in - the dynamic hardness of the material of the lower bullet reflector (N / m ² ); HD _cn - dynamic hardness of the material of the core of the bullet (N / m ² ); ρ _SP - the density of the material of the core of the bullet (kg / m ³ ); V - bullet speed at the moment of impact (m / s). 3. The bullet catcher according to claim 1, in which the upper bullet deflector is located with the angle of inclination of its front surface to the horizontal plane equal to 0-15 °. 4. The bullet catcher according to claim 1, in which the height of the lower bullet reflector is (0.7-0.9) the height of the shooting range. 5. The bullet catcher according to claim 1, in which the reflecting element adjacent to the upper bullet deflector is located at an angle β = (0.75-1.0) β _* to the horizontal, while

, where β _* is the angle of the tangent at the upper point of the lower bullet reflector to the horizontal; φ _* is the angle of the radius vector at the upper point of the lower bullet reflector. 6. The bullet catcher according to claim 1, in which the bullet chamber is made with a wall thickness (1.0-3.0) d, where d is the caliber of the weapon (m). 7. The bullet catcher according to claim 1, in which the bullet chamber is made in the form of cylindrical segments or polyhedral segments inscribed in them. 8. The bullet catcher according to claim 7, in which the cylindrical surface of the bullet chamber has a radius equal to (25-50) d. 9. The bullet catcher according to claim 1, in which the width of the horizontal entrance to the mouth of the bullet chamber is 0.150-0.450 m. 10. The bullet catcher according to claim 1, in which the upper and lower bullet reflectors, a reflecting element and a bulletproof chamber are made of material with a Brinell hardness of at least 400 units.