UA145434U - BULLETER - Google Patents

Abstract

The ball catcher consists of at least one ball receiving chamber made in the form of a hollow tube forming a container which is at least partially filled with liquid and installed at an angle to the horizontal plane, and a support structure holding the tube in the set position. The ball receiving chamber is made in the form of at least two connected sections of a cylindrical tube, which are coaxially mounted and located at an angle of inclination α to the horizontal plane selected in the range from 40 ° to 50 °. The outlet of the first ball section of the pipe is connected to the inlet of the next section of the pipe pipe. The connected sections of the pipe together form the inner space of the container, which is made with the possibility of unimpeded movement of the ball through the upper part of the pipe filled with air.

Description

The useful model belongs to the means for weapons research, in particular, but not exclusively, firearms, namely, to the designs of liquid (water) bullet arresters, designed to receive bullets (experimental projectiles) of experimental shots, and can be used in the field of forensic ballistics examinations (weapon examinations), when conducting identification studies to establish a sample of a rifled or smoothbore weapon from which bullets or elements of a multiple kinetic projectile (shotgun, buckshot) were fired.

The known liquid bullet trap (KO 53427 (01), publ. 10.05.2006, МПК Б41у 13/001, consisting of a straight pipe that is hollow from below, filled with a liquid with a density not less than the density of water, equipped with a cover clip that has a locking device with a pipe .The lid has an inlet for bullets, which is closed by a removable rubber membrane.A catch chamber with an opening bottom and a shutter is used to remove the fired bullets from the tube.

Such a technical solution is characterized by a number of disadvantages. Yes, this design is intended exclusively for obtaining bullets (experimental projectiles) of experimental shots when firing rifled firearms, it is impossible to fire multiple kinetic projectiles, which are used to identify smoothbore firearms.

The length of the pipe does not ensure a guaranteed loss of kinetic energy by the bullets (experimental projectiles) of the experimental shots when they overcome the liquid layer, which can lead to their impact on the bottom of the pipe with subsequent deformation and loss of traces of the bore on their surface.

The presence of a rubber membrane in the design makes it impossible to obtain samples of bullets (experimental projectiles) of experimental shots, which are completely made of a lead-based alloy, or expansive bullets with an exposed lead core, because as a result of hitting the membrane, they can be deformed (destroyed) with damage to the traces of the barrel on their surfaces.

In addition, wiping the surfaces of bullets (experimental projectiles) with a membrane, especially those made of a lead-based alloy, leads to distortion of the microrelief in the traces of the barrel on their surfaces.

Also known is the liquid bullet interceptor (CM 2309558 (U), publ. 03.03.1999, МПК БЕ41.) 13/00), which consists of a container for water, valves, a support frame and a table for weapons. The water container is fixed on the bracket at an angle and filled with water, and in its lower corner there are interconnected valves.

The length of the tube of the bullet catcher, like the previous one, does not ensure the guaranteed loss of kinetic energy by the bullets (experimental projectiles) of experimental shots when they overcome the layer of liquid, which can lead to their hitting the bottom of the tank with further deformation and loss of traces of the bore on their surface.

The design lacks means and structural elements that compensate for the effect of hydraulic shock, which can lead to the destruction of the bullet interceptor structure.

Also, the design of the bullet catcher is not universal, as it is intended exclusively for receiving bullets (experimental projectiles) of experimental shots when firing rifled firearms.

A liquid bullet trap is also known (KO 2499221 (С1), publ. 20.11.2013, МПК Б41) 13/00), which contains a frame on which a cylindrical body partially filled with liquid is mounted at an angle to the floor. In the front part, the case is made deaf and equipped with a means for removing the bullet, and on the back of the frame, a cartridge receiver and a device for attaching a weapon with an electric trigger, which are included in the remote control firing system, are fixed. The tool for removing the ball is equipped with an additional tap and a funnel connected in series.

Like the previous ones, this design of the bullet catcher does not provide universality, as it is intended exclusively for receiving bullets (experimental projectiles) of experimental shots when firing rifled firearms.

The angle of inclination of the pipe with the liquid can cause the liquid level and the angle of entry of the ball (experimental projectile) into it to be close to 307, and this can lead to the ricochet of the ball (experimental projectile) and its impact on the wall of the pipe with subsequent destruction of the structure of the ball (experimental projectile) and damage to the design elements of the bullet interceptor.

The entry of the bullet (experimental projectile) into the liquid by its lateral projection can lead to deformation of the bullet (experimental projectile), which will contribute to the distortion of the microrelief in the traces of the barrel on the surface of the bullets (experimental projectiles) because of experimental shots.

The known liquid bullet interceptor (ША 119271 (І), publ. 25.09.2017, IPC E41.) 13/00), which contains a metal welded body and a tank filled with water to absorb the kinetic energy of the bullet, a nozzle for shooting bullets is installed on the front wall of the tank at an angle, and on the rear wall of the tank from below at the bottom there is a rubber plate for extinguishing the residual energy of the bullet.

The disadvantages of this technical solution include the fact that the angle of inclination of the pipe with liquid 20" to the floor will lead to a guaranteed ricochet of small-caliber high-speed bullets (experimental projectiles), which, in turn, can lead to their hitting the pipe wall with subsequent destruction of the bullet structure ( experimental projectile) and equipment.

The entry of the bullet (experimental projectile) into the liquid by its lateral projection can lead to the deformation of the bullet (experimental projectile), which will contribute to the distortion of the microrelief in the traces of the barrel on the surface of the bullets (experimental projectiles) of experimental shots.

The dimensions of the tank do not ensure a guaranteed loss of kinetic energy by bullets (experimental projectiles) of experimental shots when they overcome the layer of liquid, which can lead to their hitting the bottom of the tank with subsequent deformation and loss of traces of the bore on their surface.

Also, the design lacks means and structural elements that compensate for the effect of hydraulic shock, which can lead to the destruction of the bullet interceptor structure.

The closest in technical essence to what is claimed is a liquid bullet trap

IKO 2235964 (C1), publ. 10.09.2004, IPC EG41u 13/00), consisting of at least one bullet-receiving chamber, made in the form of a hollow pipe, forming a container, which is at least partially filled with liquid, and installed at an angle to the horizontal plane, and a support structure , which holds the pipe in the installed position.

In this liquid bullet trap, the body, filled with water, is installed on a movable frame at an angle of 207... 307 to the floor. A cylindrical damper is installed in the bore of the upper flange of the case, the central hole of which is closed by a removable plug made of easily punctured material.

The disadvantages of this design are, again, the angle of inclination of the pipe with liquid 207... 30" to

From the floor, in which the ricochet of small-caliber high-speed bullets (experimental projectiles) is guaranteed, which can lead to their hitting the pipe wall with subsequent destruction of the structure of the bullet (experimental projectile) and equipment.

As in the previous technical solution, the entry of the bullet (experimental projectile) into the liquid with its lateral projection can lead to deformation of the bullet (experimental projectile), which will contribute to the distortion of the microrelief in the traces of the barrel on the surface of the bullets (experimental projectiles) of experimental shots, especially those that made of a lead-based alloy.

The presence in the design of a plug made of a material that is easily penetrated and that prevents the exit of liquid towards the weapon makes it possible to obtain samples of bullets (experimental projectiles) of experimental shots, which are completely made of a lead-based alloy, or expansive bullets (experimental projectiles) with a bare lead core, because as a result of hitting a cork, they can be deformed (destroyed) with damage to the traces of the bore on their surfaces.

This design of the bullet catcher, like the previous ones, does not provide universality, as it is intended exclusively for receiving bullets (experimental projectiles) of experimental shots when firing rifled firearms.

The basis of a useful model is the task of creating a bullet catcher that has improved operational properties, in particular, ensures versatility in its use.

The problem is solved by the fact that in a bullet trap consisting of at least one bullet-receiving chamber, made in the form of a hollow pipe, forming a container that is at least partially filled with liquid and installed at an angle to the horizontal plane, and a support structure that holds the pipe in the installed position , according to a useful model, the bullet-receiving chamber is made in the form of at least two connected sections of a cylindrical tube, which are coaxially installed and located at an angle of inclination "a to the horizontal plane, selected in the range from 40" to 50", the exit hole of the first tube section after the movement of the bullet connected to the inlet opening of the tube section following the movement of the bullet, the connected tube sections together form the internal space of the container, which is designed to ensure the unhindered movement of the bullet through the upper part of the tube filled with air, because it is adapted for the formation of a shock wave formed by powder gases close to the spherical front, bullet entry into the liquid at an angle close to the normal to its surface, and passing through the lower part of the pipe with shock-contact interaction with the liquid, and absorption of its kinetic energy.

Due to the fact that the bullet-receiving chamber is made in the form of at least two connected sections of a cylindrical tube, installed coaxially and located at an angle of inclination a to the horizontal plane selected in the range from 40" to 50", the exit hole of the first section of the tube after the movement of the bullet is connected with the inlet opening of the pipe section following the movement of the ball, the connected pipe sections together form the internal space of the container, it is possible to significantly increase the dimensions of the container (reservoir), especially its length, and the versatility of the design due to the possibility of equipping it, if necessary, with additional sections for increasing total length

Also, with such a design, it is possible to expand the range of low-energy striking elements that can be examined with the help of a bullet interceptor, due to the rather significant length of the bullet receiving chamber, which, in turn, allows you to protect the elements of the bullet interceptor design from damage by bullets (experimental projectiles) capable of layers of liquid (aqueous) medium to move over fairly significant distances.

At the same time, due to the installation of the bullet trap at an angle of inclination a to the horizontal plane selected in the range from 40" to 50", it becomes possible to install the bullet trap in rooms with limited space, which is characteristic of basement rooms, in which, for reasons of security, usually they are installed.

Due to the fact that the connected sections of the pipe jointly form the internal space of the container, which is made with the possibility of ensuring the unhindered movement of the bullet through the upper part of the pipe filled with air, adapted for the formation of a shock wave close to the spherical front formed by the powder gases, the entry of the bullet into the liquid at an angle close to normal to its surface, and passing through the lower part of the pipe with shock-contact interaction with the liquid, and absorption of its kinetic energy, the formation of a spherical shock wave is ensured, which moves in front of the bullet (experimental projectile), which is formed due to the outflow from the barrel of powder gases from at a speed that significantly exceeds the speed of the bullet

Zo (experimental projectile).

Thanks to the phenomena described above, near-optimal conditions for the entry of a ball (experimental projectile) into a liquid are formed at an angle close to the normal to the surface of the liquid at the point of entry, since the spherical front of the shock wave upon contact with the liquid forms its surface close to concave, which is preserved due to inertia liquid until the bullet (kinetic projectile) enters it.

In this way, the possibility of the bullet (experimental projectile) ricocheting from the surface of the liquid is excluded, and its contact with a lateral projection is excluded, which contributes to the preservation of the microrelief of the traces of the barrel from direct impact-contact interaction with the liquid environment. After entering the liquid column, due to a significant increase in the resistance forces of the environment, the bullet (experimental projectile) loses its stability and kinetic energy, due to which the microrelief of the traces of the barrel remains intact.

It is expedient that the support structure holding the pipe in the installed position includes a supporting frame mounted on a plurality of vertically installed racks of variable height, and is equipped with at least one ladder and at least one operating platform.

This variant of execution ensures the convenience of operation of the bullet catcher due to free access to the upper part of the bullet receiving chamber for mounting the weapon for shooting, and carrying out the shooting process.

Also, it is advisable to use a mixture of water and an antiseptic with a density not less than that of water as a liquid.

This version of the implementation ensures an increase in the service life of the liquid (water) in the tank of the bullet catcher, while at the same time preserving the conditions to exclude the formation of damage on the surfaces of the tested bullets (experimental projectiles), and preserving the microrelief in the traces of the barrel.

A possible version of the bullet catcher, in which it is suitable for receiving bullets from experimental shots from rifled or smoothbore weapons.

There is also a variant of the bullet catcher in which it is suitable for obtaining traces of the barrel bore on the surfaces of low-velocity or high-velocity bullets of experimental shots.

Another possible version of the bullet catcher - in which it is suitable for obtaining traces of the barrel bore on the surfaces of shellless bullets of experimental shots.

In general, the set of features of the design of the bullet catcher described above ensures versatility and improvement of its operational properties, in particular: - allows multiple shots from one sample of a weapon to receive several experimental samples of bullets (experimental projectiles) at the same time, without damaging the latter as a result of hitting the bullets (experimental projectiles) one-to-one, which is characteristic of other types of bullet interceptors; - provides for samples of weapons with a low rate of fire, the ability to shoot in automatic mode with a limited number of cartridges, without damage to the fired bullets (experimental projectiles) due to their collision in the layer of the medium (liquid); - excludes the need to dismantle the cartridges under investigation to reduce their powder charge, which is sometimes carried out when firing from long-barreled and medium-barreled weapons with a full charge, due to the fact that bullets (experimental projectiles) can hit the wall or bottom of the bullet chamber, respectively, exclude the destruction and damage of the bullet catcher, and the loss of personal signs of microrelief in the tracks; - allows shooting from smoothbore weapons with multiple kinetic projectiles (cartridge, shot) or complex bullets (experimental projectiles) with tracking surfaces.

The essence of the useful model is explained by the drawings, where in fig. 1 shows a bullet trap, a side view, in fig. 2 - bullet trap, front view, in fig. C - bullet trap, top view.

The bullet catcher consists of a bullet receiving chamber 1, which, in turn, is formed from two connected sections of a cylindrical pipe 2, 3, which have a large diameter.

The outlet opening of the first moving ball of pipe section 2 is connected to the entering opening of the next moving ball of pipe section 3, pipe sections 2 and 3 are connected to each other, installed coaxially, and together form container 4 (reservoir for liquid). As a liquid, preferably, a mixture of water and an antiseptic is used, with a density not less than the density of water.

The connected sections of the cylindrical pipe 2, C are located at an angle of inclination a to the horizontal plane, selected in the range from 40" to 50", however, the most optimal angle is close to 45".

The internal space of the container 4 is designed in such a way that it ensures the unhindered movement of the ball (experimental projectile) through the upper part of the pipe 5, which is filled with air, and is adapted to the formation of a spherical shock wave formed by the powder gases in the container 4, ensuring the entry of the ball (experimental projectile) into the liquid at an angle close to the normal to its surface, and passing through the lower (lower located) part of the pipe 6 filled with liquid, moves in the liquid with shock-contact interaction with it, and absorption of the kinetic energy of the bullet (experimental projectile).

The connection of sections of the cylindrical pipe 2, C between themselves is preferably provided by flanges 7 connected by a bolted connection. However, other connection options are also possible, for example, by placing sections of the cylindrical pipe 2, C one inside the other, provided that the ball moves freely through the inner space of the container 4.

The two-section design described above is the most optimal, which allows you to obtain traces of the barrel channels on the surfaces of various types of striking elements in a fairly wide range of their initial speeds, however, the number of sections used can be easily increased if necessary.

It is also possible for the upper part of the tube 5 to have a means for mounting and holding the weapon (not shown in the figure).

To ensure the tightness of the bullet-receiving chamber 1 and to reduce the noise level, gaskets made of waterproofing material (for example, rubber) are placed between the adjacent flanges 7 of the sections of the cylindrical tube 2, C and between the lower flange 8 and the bottom 9 of the bullet-receiving chamber 1.

The bottom 9 of the bullet-receiving chamber 1 contains a drain pipe 10 equipped with two shut-off valves and a valve (not shown in the figure). The drainage pipe 10 has a shape that makes it possible to form two zones, the first zone in which, without any additional equipment, under the influence of gravity, shot bullets accumulate, which are placed exclusively in the space in front of the first cut-off valve, and the second zone - for removing shot bullets balls, in front of the second shut-off valve, into which they move under the pressure of liquid and gravity after opening the first shut-off valve.

The valve allows for the release of excess liquid pressure, the appearance of which is caused by the action of a shock wave, which is formed during a shot and is transmitted to the liquid medium.

It is also possible for the bullet-receiving chamber 1 to be installed in the housing (not shown in the figure), and in the cavity between the housing and the bullet-receiving chamber 1, a sound-absorbing material was placed.

The bullet-receiving chamber 1 is mounted on a support structure that holds the connected sections of the cylindrical tube 2, C in the set position. The support structure includes a supporting frame 11, which is installed on a set of vertically installed racks 12, which have a variable height, which corresponds to the height of the connected sections of the cylindrical pipe 2, C in the place where they rest on it, and have at least three-position fixation.

An operational platform 13, consisting of a frame 14 and a deck 15, is installed on the support structure, stairs 16 are attached to the operational platform 13.

All structural elements, in particular, sections of the cylindrical pipe 2, 3, supporting frame 11 are made of metal, preferably stainless steel, which minimizes the effect of corrosive processes of the liquid (water) environment on the durability of the structure (practically ensuring an unlimited service life of the bullet catcher), and contributes to reliability structures.

At the same time, it is possible to use standard metal profiles and pipes for the manufacture of structural elements, and to combine the structural elements with electric arc welding and standardized fastening elements (bolts, nuts, etc.), which ensures high manufacturability of the structure.

The bullet trap works as follows.

In order to preserve the traces of the bore, which are reproduced on the surfaces of bullets (experimental projectiles), the bullet interceptor uses the principle of destabilization of the flight of bullets (experimental projectiles) in an environment whose density significantly exceeds the density of air. As such medium, a liquid is used, preferably water with special antiseptic additives, with a density not less than the density of water.

The angle of entry of the ball (experimental projectile) at an angle to the surface of the liquid close to 45" under normal conditions has negative consequences, and significantly affects the conditions of contact of the ball (experimental projectile) with the liquid medium, as it can lead to ricochet

From a bullet (experimental projectile) with its subsequent destruction and fragmentation into separate parts, which is unacceptable.

The most optimal angle of encounter of a bullet (experimental projectile) with the surface of a medium with a high density is the impact-contact interaction with the angle of entry into the liquid medium, which is close to the normal to the specified surface of the liquid.

In the bullet trap of the design described above, the creation of optimal conditions for the entry of the bullet (experimental projectile) into the liquid medium is achieved as follows.

During the shot, the bullet (experimental projectile), after leaving the barrel, travels in the air for a rather insignificant period of time, namely at a distance from the muzzle of the barrel of the weapon under study, and to the surface of the liquid. This time is enough to create optimal conditions for the entry of the bullet (experimental projectile) with its main part, and not with its side projection.

This is due to the fact that the powder gases, which flow out of the barrel after the bullet (experimental projectile), are in a practically closed volume of container 4, and have a higher speed than the bullet (experimental projectile), and at the same time have significant pressure. Together, this contributes to the formation of a shock wave that moves in front of the sphere (experimental projectile) and has a spherical front, which, upon contact with the liquid medium, forms a concave surface in it, which is close to spherical or parabolic.

Such a concave shape of the surface of the liquid is preserved almost until the moment of entry of the ball (experimental projectile) due to the inertia of the liquid. As a result, the entry of the main part into the layer of liquid in container 4 is carried out almost under optimal conditions.

In this way, possible negative consequences due to the entry of the ball (experimental projectile) into the liquid layer by its lateral projection are excluded.

For low-energy balls (experimental projectiles), after they enter the liquid column, the density of the medium increases sharply, which contributes to the formation of a significant moment of the reaction forces of the medium (resistance forces of the medium), which contributes to the overturning of the ball (experimental projectile) and thus leads to destabilization.

Since the amplitude of oscillation of the ball (experimental projectile) increases, the surface area of its contact with the environment also increases, with a corresponding increase in the resistance forces of the environment. The kinetic energy of the ball (experimental projectile), which is spent on overcoming the resistance forces of the liquid medium, leads to the damping of its further movement, and its descent to the bottom of container 4 under the influence of gravity.

For high-energy bullets (experimental projectiles), the speed of which exceeds 100...200 m/s, destabilization of their further movement occurs as follows.

When entering the liquid layer around the balls (experimental projectiles), which have a relatively small length, a cavity is formed, which for a certain time moves with the projectile in the liquid medium layer, the walls of the cavern collapse under the pressure of the liquid behind the bottom part of the experimental projectile.

Moving in the cavern at the initial part of the trajectory in the liquid medium layer, due to nutation and precessional oscillations, the sphere (experimental projectile) begins to contact its surface with the walls of the cavern, which leads to an increase in the amplitude of the oscillation of the sphere (experimental projectile) due to the action of reaction forces from the medium with subsequent destabilization of the bullet (experimental projectile). As a result, under the action of the resistance forces of the liquid medium, the speed of the ball (experimental projectile) is sharply reduced. Further processes are similar to those described above for low-energy bullets (experimental projectiles).

The bullet interceptor of the described design allows you to obtain experimental samples of bullets (experimental projectiles) with traces of the barrel bore at their initial velocities of up to 900...950 m/s for "Yeshiya Meta! dasKei" type bullets, and up to 500...600 m/s for bullets from the types "Zoi Roip!" and "Noiom/ Roipi", and is suitable for shooting all types of rifled and smoothbore weapons, except for 12.7 mm and 14.5 mm caliber weapons.

Claims (1)

USEFUL MODEL FORMULA 1. Bullet trap, consisting of at least one bullet receiving chamber, made in the form of a hollow tube, forming a container that is at least partially filled with liquid, and installed at an angle to the horizontal plane, and a support structure that holds the tube in the installed position, which is characterized by , that the bullet-receiving chamber is made in the form of at least two connected sections of a cylindrical tube, which are coaxially installed and located at an angle of inclination "a to the horizontal plane, selected in the range from 407 to 50", the outlet of the first section of the tube after the movement of the bullet is connected to the inlet of the next according to the movement of the ball of the pipe section, the connected pipe sections together form the internal space of the container, which is made with the possibility of ensuring the unhindered movement of the ball through the upper part of the pipe, filled with air, adapted for the formation of a shock wave close to the spherical front formed by powder gases, the entry of the ball into the liquid an angle close to the normal to its surface, and passing through the lower part of the pipe with impact-contact interaction with the liquid, and absorption of its kinetic energy. 2. Bullet interceptor according to claim 1, characterized in that the support structure that holds the pipe in the installed position includes a supporting frame mounted on a plurality of vertically installed racks of variable height and equipped with at least one ladder and at least one operating platform. 3. The bullet trap according to claim 1 or claim 2, which differs in that a mixture of water and an antiseptic with a density not less than the density of water is used as a liquid. 4. The bullet catcher according to claim 1, which is characterized by the fact that the bullet receiving chamber is made with the possibility of receiving bullets from experimental shots from rifled or smoothbore weapons. 5. The bullet catcher according to claim 1, which is characterized by the fact that the bullet receiving chamber is made with the possibility of obtaining traces of the barrel bore on the surfaces of low-velocity or high-velocity bullets of experimental shots. 6. The bullet catcher according to claim 1, which is characterized by the fact that the bullet receiving chamber is made with the possibility of obtaining traces of the barrel bore on the surfaces of shellless bullets of experimental shots. (with; - 11. and and 5 And we 12 Fig. 1 T-- Tsnya -Z3 c. - Y 10-- IM | - Fig. 2 sh SHY 2 in THIS sh-! And led / her, and 8 Fig. 3