RU2733018C1 - Device for underwater shooting from small arms - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: device for underwater firing from small arms in the first embodiment includes small arms with ammunition, casing with inner cavity and through hole, which is intended for bullet span during firing and is closed by muzzle valve prior to firing. In the second embodiment, device for underwater firing from small arms includes small arms with ammunition, casing with inner cavity and through hole, which is intended for bullet span during firing. In lower wall of casing there is at least one bottom window for charging small arms with ammunition and for control of safety and firing mechanisms of small arms. Barrel with automatics assemblies of small arms is arranged in inner cavity of casing.

EFFECT: technical result is increase in efficiency and safety of underwater shooting from small arms.

14 cl, 4 dwg

Description

The invention relates to a device for small arms, providing the possibility of underwater shooting from small arms, including from sports and hunting firearms.

The relevance of creating a device for underwater shooting is due to the fact that ammunition with a cavitating core (underwater bullet) for firing in water and from air into water is known (see RF patents No. 2 268 455 C1 from 20.01.2006 and No. 2 316 718 C1 from 10.02 .2008; as well as US patent No. US 8,082,851 B2 dated 12/27/2011; European patent No. EP 2 053 342 B1 dated 06/18/2014 and Norwegian patent No. NO 339 365 dated 12/05/2016).

Shooting from the air into the water with an underwater bullet is possible from any firearm. However, when water enters the barrel and when an underwater bullet collides with a water plug in the barrel, a sharp increase in the pressure of the powder gas occurs, and the primer flies out of the sleeve.

Ammunition with an underwater bullet, intended for firing in water from a weapon filled with water, is called "underwater ammunition" and has a special powder charge that provides an allowable pressure in the barrel when fired in water and does not significantly increase the hydraulic pressure in the area where the bullet enters the water. With an increased hydraulic pressure in the zone of the bullet entering the water, the dimensions of the formed cavity decrease, and the underwater bullet is inhibited by viscous flow around the water at the initial section of the underwater trajectory. However, the muzzle velocity of underwater bullets of underwater ammunition is lower than the muzzle velocity of similar underwater bullets in ammunition intended for firing from air into water.

For example, when fired in the water with a 308 Win. (7.62 × 51) from a 406mm (16 ") long barrel filled with water, an underwater bullet weighing 16g has an initial velocity of V = 455 m / s at a maximum pressure of P = 340 MPa. When this underwater ammunition is fired from air into water or under water from dry the barrel closed with a membrane, this underwater bullet has an initial velocity of V = 575 m / s at a maximum pressure of P = 210 MPa.

In ammunition of caliber 308 Win. (7.62 × 51), designed for firing from air into water, this 16g underwater bullet has an initial velocity V = 615 m / s at a maximum pressure of P = 340 MPa. However, when this ammunition is fired under water from a dry barrel closed with a membrane, but without a muzzle expansion chamber to reduce muzzle pressure, the powder charge of this ammunition significantly increases the hydraulic pressure in the bullet entry zone into the water, while the size of the cavity is significantly reduced and the underwater bullet immediately stops in water.

Shooting underwater ammunition in water from a water-filled weapon is accompanied by the expulsion of water from the barrel with powder gas. Moreover, when shooting in water from small arms with a rate of fire of 500 - 800 rounds per minute, the barrel is filled with water between shots. The short time of filling the barrel with water (less than 0.1 sec) is due to the fact that the sleeve removed from the barrel and the ammunition sent to the barrel forcibly pump water into the barrel, like pump pistons. Moreover, all types of Kalashnikovs, "SKS-45", "SVD" and their hunting analogs, as well as many types of rifles with a short stroke of the gas piston, for example, "FN SCAR-L", "FN SCAR-N", "SL -8 "," LMT-Piston "and others work when firing underwater ammunition in the water.

However, not all types of small arms can be used for shooting in water. Automatics of gas-operated rifles without a gas piston "AR-15" and "AR-10" and their analogues do not work in water, and the firing mechanism of rifles "NK 416" and "NK 417" does not work in water when using "hard" capsules in the casings underwater ammunition.

A device for underwater shooting from small arms, which allows to shoot ammunition with an underwater bullet from a dry barrel of small arms underwater, can increase the effectiveness of underwater shooting, for example, when spearfishing and protecting bathing people from attacks by marine predators.

A device for underwater shooting is known, including a rapid-fire cannon located in the water, in which a blank shot pushes water out of the barrel before combat firing (see US patent No. 5,639,982, IPC ⁶ F41F 3/07 from 17.06.1997).

However, this device cannot be considered as a device for firing a dry barrel under water, since at a rate of fire of 500 - 800 rounds per minute the barrel will be completely filled with water between an idle and a live shot. In the case of using a revolving cannon, for example, the GIAT 30M791 with a rate of fire of 2500 rounds per minute, the barrel will be partially filled with water between a blank and a live shot, and the projectile will collide with a water plug in the barrel.

A device for underwater shooting is known, including a barrel with a muzzle brake located in the water, in which an annular membrane closes its side openings, and a disc membrane closes the muzzle opening of the muzzle brake (see US patent No. US 7,237,353 B1, IPC ⁷ F41A 21/46 from 03.07 .2007). In this device, before firing, the gas mixture supply system equalizes the pressure inside the barrel with the external water pressure. When fired, the propellant gas breaks the annular membrane of the muzzle brake and partially flows out into the water through its side holes, and the projectile and the shedding pan break through the disc membrane of the muzzle brake and enter the water.

However, this device cannot be used for repeated rapid-fire firearms, as the small volume muzzle brake and barrel will be filled with water after the first shot.

A device for underwater shooting is known, including a barrel located in the water with a closed muzzle device equipped with a controlled muzzle valve, the passage opening of which is intended for the passage of an underwater projectile when fired (see US patent No. US 5,966,858, IPC ⁶ F41A 21/46 dated 19.10.1999 ). This device includes a gas mixture supply system and a propellant gas outflow system, a firing control mechanism and a muzzle valve control device for opening the muzzle valve until the propellant charge is ignited. When fired, the propellant gas expands in the muzzle device and is partially bypassed into the propellant gas outflow system, and the main propellant gas flow exits through the muzzle valve into the water together with the underwater projectile.

However, to reduce the muzzle pressure of the propelling gas and prevent an increase in hydraulic pressure in the area of the projectile entry into the water, the volume of the expansion chamber of the muzzle device must be many times greater than the volume of the barrel bore, which is not provided for in this device.

Perhaps this device with gas mixture supply systems, propellant gas outflow and with a muzzle valve control mechanism can be used in underwater artillery, but this device is inappropriate to use for underwater shooting from existing small arms, since additional units will significantly increase the total weight of the rifle complex and reduce its mobility.

Known devices for underwater shooting, including a barrel located in the water with various controlled muzzle valves that prevent water from entering the barrel before a shot and between shots (see US patents No. US 7,681,352 B2, IPC ⁷ F41C 9/06, dated 03.23.2010; No. US 7,832,134 B2, IPC ⁷ F41C 9/06 dated November 16, 2010; No. US 7,874,091 B2, IPC ⁷ F41C 9/06 dated January 25, 2011; No. US 8,042,295 B2, IPC ⁷ F41C 9/06 dated October 25, 2011 and US No. 8,046,947 B2, IPC ⁷ F41C 9/06 dated 01.11.2011).

In the first version of the device, the muzzle valve is opened using a piston that moves at the moment the projectile moves in the barrel under the action of the propellant gas discharged from the barrel, or the muzzle valve is opened using an electric motor, which operates on a signal from the firing control.

In the second version of the device, the muzzle valve is made in the form of a turbine rotated by an electric motor, which prevents water from entering the barrel between shots and is powered by an additional engine, and before firing, the barrel is covered with a membrane, which is pierced by the projectile at the first shot.

In the third version of the device, the muzzle valve is made in the form of a disc, which, upon a signal from the firing control means, moves in the water by an electromagnetic field generated in the water by an electromagnetic coil mounted on the barrel.

In the fourth version of the device, various muzzle valves are made in the form of a plurality of sealing elements controlled by additional actuators and firing control means, which break off and close when the projectile is flying, preventing water from entering the barrel before firing and between shots.

In the fifth version of the device, the well-known Helmholtz resonator is used in the muzzle valve, which prevents water from entering the barrel between shots and operates from an additional source of compressed air on a signal from the firing control, and before firing, the barrel is covered with a membrane, which is pierced by the projectile at the first shot.

These options show that the actual performance of these devices is questioned by the authors of these inventions, therefore, many technical solutions are proposed for the possibility of underwater shooting from dry weapons.

However, all these devices do not provide for a decrease in the muzzle pressure of the propelling gas to prevent an increase in the hydraulic pressure in the area of the projectile entry into the water, and this significantly worsens the parameters of the projectile, which will be slowed down by viscous water flow at the initial section of the underwater trajectory.

In addition, these devices are impractical to use for underwater shooting from existing small arms, since additional engines and units will significantly increase the weight of the rifle complex and reduce its mobility.

The closest analogue (prototype) of the claimed invention is a device for underwater shooting from firearms, including a sealed casing with a controlled muzzle valve, the passage opening of which is intended for the passage of an underwater projectile when fired, and weapons and ammunition are completely placed inside the casing (see RF patent No. 2 498 189 C2, IPC ⁷ F41С 9/06 dated November 10, 2013; US patent No. US 8,919,020 В2 IPC ⁷ F41С 9/06 dated December 30, 2014 and European patent No. EP 2 690 390 В1, IPC ⁷ F41С 9/06 dated 10.08 .2016). In this device, the fire control device is equipped with pyrotechnic cartridges, each of which, before each firing, creates an increased pressure of the pyrotechnic gas inside the casing, which exceeds the external water pressure. The increased pressure in the casing opens the muzzle valve, which acts on the firing mechanism of the weapon for firing. During automatic firing, the propellant gas flowing out through the bore prevents water from entering the casing. Moreover, the expansion of the powder gas in a large volume of the casing reduces the pressure of the gas flowing out through the passage hole into the water, which excludes an increase in the hydraulic pressure in the zone of the projectile entry into the water. After stopping firing, the muzzle valve closes as a result of a decrease in gas pressure inside the casing, and the weapon with the remaining ammunition remains dry and ready for the next firing.

However, this device requires depressurization of the casing in the air to replenish the weapon with ammunition, which reduces the effectiveness of spearfishing when using weapons with a small amount of ammunition, especially in the open sea.

In addition, this device requires the installation of a loaded weapon in it and does not allow visual control of the safety and firing mechanisms, which, from the point of view of safety requirements, limits its use in sports shooting in Aquatir (see RF patent No. 2 316 712 C2 dated 10.02. 2008; US patent No. US 7,942,420 B2 dated May 17, 2011; European patent No. EP 1 884 736 B1 dated May 29, 2013).

In addition, the practice of spearfishing and sports shooting in "Aquatira" revealed the need for rapid replenishment of small arms ammunition in order to increase the effectiveness of spearfishing and to increase the entertainment of sports competitions in "Aquatira".

The objective of this invention is to improve the efficiency and safety of underwater shooting from small arms.

The solution to the problem is achieved by the fact that in a device for underwater shooting from small arms, including small arms with ammunition, a casing with an internal cavity and a passage hole, which is designed for the passage of a bullet when fired and is closed by the muzzle valve before firing, according to the invention, in the lower wall of the casing, at least one bottom window is made for loading small arms with ammunition, and for controlling the safety and firing mechanisms of small arms, while at least the barrel with small arms automation units is placed in the inner cavity of the casing.

Within the framework of the present invention, small arms automation units are understood as mechanisms and parts of small arms that ensure automatic reloading of the weapon (extraction of the cartridge case and sending the ammunition into the chamber).

The set of features of the invention, indicated in the independent claim, increases the efficiency and safety of underwater shooting from small arms, and has the following differences from the prototype and the prior art:

- it is possible to fire from a dry barrel of small arms under water when placing at least the barrel with the automatic units of the weapon in the inner cavity of a non-closed casing, filled with air before firing, but during firing filled with powder gas, which prevent water from entering the casing;

- provides the ability to select the type of ammunition and loading weapons under water before the start of firing and replenishment of the weapon with ammunition during firing;

- the possibility of visual control under water of the safety and firing mechanisms of small arms located inside and outside the casing is provided.

In a preferred embodiment of the invention, the casing is provided with pressurizing means for supplying the gas mixture into the interior of the casing.

This option increases the efficiency of the invention due to the possibility of removing water from the internal cavity by filling the internal cavity with a mixture of gases from a scuba gear or "air" (a mixture of gases) exhaled by a swimmer through a pressurization tube when the external water pressure rises with an increase in the depth of fire or in case of overturning the device in water ... In addition, the filling of the inner cavity can also be provided with a carbon dioxide cartridge for pneumatic weapons equipped with a gas reducer or in another known manner.

In addition, the solution to the problem is achieved by the fact that in a device for underwater shooting from small arms, including small arms with ammunition, a casing with an internal cavity and a through hole, which is intended for the passage of a bullet when fired, according to the invention, is made in the lower wall of the casing, at least one bottom window for loading small arms with ammunition, and for controlling the safety and firing mechanisms of small arms, while at least a barrel with small arms automation units is located in the inner cavity of the casing, and for firing underwater ammunition with underwater bullet, intended for shooting in water.

The set of features of the invention, indicated in the second independent claim, increases the safety and efficiency of underwater shooting from small arms, and has the following differences from the prototype and the prior art:

- the device does not have a muzzle valve, and for firing, underwater ammunition intended for shooting in water is used, and the first shot is fired from a small arms filled with water and an internal cavity filled with water;

- at the first shot, the powder gas removes water from the weapon and the inner cavity, and further shooting is carried out from a dry barrel with small arms automation units placed in the inner cavity of an open casing filled with powder gas, which prevents water from entering the casing;

- provides the ability to select the type of ammunition and loading weapons under water before the start of firing and replenishment of the weapon with ammunition during firing;

- the possibility of visual control under water of the safety and firing mechanisms of small arms located inside and outside the casing is provided.

The invention is explained in more detail on specific examples of its implementation, which in no way limit the scope of claims, but is intended only for a better understanding of its essence by a specialist.

When describing an example of a specific implementation of the invention, reference is made to the accompanying drawings, which show:

Fig. 1 shows a first embodiment of the invention;

Fig. 2 shows a second embodiment of the invention;

figure 3 is a third embodiment of the invention;

Fig. 4 shows a fourth embodiment of the invention.

Figure 1 shows a longitudinal section of the proposed device before firing in water with a hunting self-loading carbine "Saiga-308-1" for ammunition of caliber 308 Win. (7.62 × 51) with standard muzzle brake and detached stock.

The device for underwater shooting includes a casing 1 with an inner cavity 2 and a through hole (D), which is made in the bushing 14, is intended for the passage of a bullet when fired and is closed by a muzzle valve 3. A bottom window is made in the bottom wall of the casing 1 4. The barrel of the weapon 5 s muzzle brake 7 and automation units, as well as the safety box 9 and the bolt handle 10 are located in cavity 2. In this case, the weapon handle 5, ammunition magazine 6, magazine latch 12 and trigger 11 protrude from cavity 2. Width of casing 1 and bottom windows 4 provide the ability to load weapons, control parts 9-10, extract the cartridge case and remove the ammunition from the chamber.

The weapon 5 is fixed in the casing 1 by a pin 13 and a tight mating of the muzzle brake 7 with the tapered surface (C) of the sleeve 14, fastened by a tightening threaded connection to the nut 15, which is fixed in the casing 1. This ensures reliable fastening of the weapon 5 in the casing 1 and a symmetrical mating of the channel barrel with bore (D). The muzzle valve 3 is fastened with a threaded connection to the sleeve 14.

The diameter of the bore (D) is 1.03 - 1.08 of the diameter of the rifled bore, measured along the groove fields, provides free flight of the underwater bullet in the bore (D) and compensates for the possible technological inaccuracy of mating the bore of the weapon 5 with the bore (D ). With the total area of the gas outlet ports 8 of the muzzle brake 7 exceeding 4 - 6 times the cross-sectional area of the barrel bore, the size (L) between the muzzle end of the muzzle brake 7 and the muzzle end of the sleeve 14 is 5 - 8 barrel calibers. This provides the necessary expansion of the powder gas when it flows out through the gas outlet ports 8 into the cavity 2, reduces the pressure of the powder gas flowing out from the through hole (D) into the water, and eliminates the increase in hydraulic pressure in the area of the bullet entry into the water.

The casing 1 is made of impact resistant plastic or aluminum alloy. Sleeve 14 and nut 15 are made of steel. The muzzle valve 3 is made of fragile plastic such as polyethylene terephthalate (Ertalyte PET-P), which collapses when it is shot by a bullet into fragments that are separated from the threaded part of the sleeve 14 and do not prevent the installation of a new muzzle valve 3 when firing is stopped. However, when firing underwater bullets made of copper or soft brass, their nose can deform when they break through fragile plastic. In this case, it is advisable to make the muzzle valve 3 from a plastic material, for example, fluoroplastic F-4, in which, when fired by a bullet, an even bullet hole is formed without cracks and burrs. The dimensions of the casing 1 and the volume of the cavity 2 provide the device with the weapon 5 with positive buoyancy, which excludes flooding and loss of the device before firing. The location of the weapon 5 in the casing 1 provides the device with a stable horizontal position in the water with the bottom window 4 down, and the mixture of gases in the cavity 2 keeps water at the level of the bottom window 4 according to the principle of a diving bell.

Preparation of the device for underwater shooting is carried out when the device is lowered from the air into the water with the bottom window 4 down. In this position, the air (mixture of gases) in cavity 2 keeps water at the level of the bottom window 4. When loading the weapon 5, a magazine 6 with the selected type of ammunition is installed, the fuse box 9 is transferred to the firing position, the bolt handle 10 is pulled back and released forward, when This wet ammunition is sent from the magazine 6 to the chamber of the weapon 5. Moreover, the use of wet ammunition provides additional cooling of the barrel of the weapon 5 during firing and increases the survivability of the barrel.

With increasing depth of fire, increased external water pressure begins to fill the cavity 2 through the bottom window 4, compressing the gas mixture in it. A rise in the water level in cavity 2 is permissible up to the barrel with automatic units, which limits the firing depth to 6 - 8 m. To keep the water level in cavity 2 at an acceptable level at an increased depth of fire and to remove water from cavity 2 in the event of the device overturning and / or replacing the muzzle valve 3 in water, the casing 1 is equipped with a flexible pressurization tube 16 to fill cavity 2 with exhaled swimmer air "(with a mixture of gases).

The shot occurs when the trigger 11 is pressed. When fired, the underwater bullet destroys the muzzle valve 3 and enters the water, and the powder gas flowing out into the passage hole (D) forms a gas bubble in front of the muzzle end of the sleeve 14, which prevents water from entering the passage hole (D). In this case, the powder gas flowing out from the gas outlet ports 8, from the holes 17 of the gas tube and from the chamber of the weapon 5 during the extraction of the sleeve, accumulates in the cavity 2, flows out through the bottom window 4 and maintains excess pressure in the gas outlet ports 8 and the through hole (D). The increased pressure of the powder gas in cavity 2 is maintained for about one second and allows you to shoot at any angle to the horizon. At this second, the second shot can be fired, and the next second - the third shot, namely, you must shoot at a rate of fire of at least 60 rounds per minute. Such shooting is possible from semi-automatic small arms, since in a second you can press the trigger 11 two or three times. Moreover, such shooting is possible from automatic small arms with a rate of fire of 500 - 800 rounds per minute.

In contrast to the prototype, in the claimed device, when firing is stopped and the pressure of the powder gas in cavity 2 is equalized with external water pressure, water fills cavity 2 through the bottom window 4 and squeezes out the powder gas into the passage hole (D), the bubbles of which prevent water from entering the passage hole (D). The time for filling the cavity 2 with water depends on the flow rate of the propellant gas through the passage hole (D) and on the volume of the cavity 2. In the device shown in Fig. 1, the time for the rise of water from the bottom window 4 to the level of the barrel is four seconds. This means that taking into account the time of increased pressure in cavity 2 after the shot, you can wait five seconds and fire from a dry barrel, while the powder gas will remove all the water from cavity 2, so you can wait another five seconds and fire again, etc. This means that the device shown in Fig. 1 allows you to use up the entire magazine 6 of the weapon 5 when using one muzzle valve 3 at a rate of fire of at least 12 rounds per minute, which allows you to calmly aim with each shot, for example, in sports shooting in Aquatir ". Moreover, within five seconds, you can replace the magazine 6 with ammunition and continue shooting.

The practice of spearfishing shows that it is necessary to carry out 5 - 6 shots in 2 - 3 seconds for an underwater bullet to hit the vulnerable zone of a moving hunting object with an area of 0.5 - 0.8 m ² at a distance of 5 - 10 m. Therefore, the use of a standard magazine for the Saiga-308-1 hunting carbine, which has five or eight rounds of ammunition, can provide this condition when firing ammunition with an underwater bullet.

An underwater brass bullet weighing 8.0 g of ammunition 308 Win. (7.62 × 51) for shooting from air into water has the following parameters:

- initial speed V = 820 m / s and energy E = 2690 J;

- speed V = 450 m / s and energy E = 810 J at an underwater distance of 4 m;

- speed V = 250 m / s and energy E = 250 J at an underwater distance of 8 m,

At the same time, the practice of spearfishing shows that a 7.62 mm underwater bullet with an energy of approximately E = 250 J can ensure the defeat of a hunting object weighing up to 100 kg.

An underwater brass-lead bullet weighing 8.7 g with a detachable ammunition pan 308 Win. (7.62 × 51) for firing from air into water with a total projectile mass of a bullet of 10.5 g has the following parameters:

- initial speed V = 720 m / s, energy E = 2255 J;

- speed V = 535 m / s and energy E = 12450 J at an underwater distance of 4 m;

- speed V = 400 m / s and energy E = 700 J at an underwater distance of 8 m;

- speed V = 240 m / s and energy E = 250 J at an underwater distance of 15 m.

An underwater heavy bullet weighing 14.0 g with a detachable ammunition pan 308 Win. (7.62 × 51) for firing from air into water with a total projectile mass of a bullet of 16.0 g has the following parameters:

- initial speed V = 615 m / s and energy E = 2645 J;

- speed V = 510 m / s and energy E = 1820 J at an underwater distance of 4 m;

- speed V = 425 m / s and energy E = 1265 J at an underwater distance of 8 m;

- speed V = 190 m / s and energy E = 250 J at an underwater distance of 26 m,

With an increase in the time between shots (more than five seconds), the shooter can fire a shot from a water-filled weapon with an ammunition intended for firing from air into water. In this case, the primer will fly out of the sleeve due to a sharp increase in pressure, and part of the powder gas will flow out through the primer hole, while the average pressure of the powder gas in the barrel will decrease and the initial bullet velocity will decrease, and the weapon's automatic equipment will not be able to reload the weapon for the next shot.

For training in shooting and increasing the safety of shooting, it is advisable to use underwater ammunition designed for shooting in water. In this case, it is not necessary to install the muzzle valve 3 on the sleeve 14, but it is necessary to fire the first shot from the cavity 2 and weapon 5 filled with water. At the first shot, the powder gas removes water from the weapon 5 and cavity 2, and further firing is carried out from a dry barrel with automatic units small arms 5, placed in a cavity 2 filled with propellant gas, as described above. With an increase in the time between shots (more than five seconds), cavity 2 and weapon 5 are filled with water, which is removed by the first shot in the next series of shots. At the same time, the parameters of the first bullet in a series of shots correspond to those of a bullet when firing from a water-filled small arms barrel, but the parameters of the next bullets in a series of shots fired from a dry barrel are approximately equal to the parameters of ammunition bullets intended for firing from air into water.

For example, an underwater brass bullet weighing 8.0 g of an underwater ammunition 308 Win. (7.62 × 51) has the following parameters:

a) when firing from a barrel filled with water:

- initial speed V = 510 m / s and energy E = 1040 J;

- speed V = 280m / s and energy E = 315 J at an underwater distance of 4m;

- speed V = 240 m / s and energy E = 230 J and at an underwater distance of 5 m;

b) when shooting from a dry barrel into the water:

- initial speed V = 600 m / s and energy E = 1440 J;

- speed V = 335 m / s and energy E = 445 J at an underwater distance of 4 m;

- speed V = 250 m / s and energy E = 250 J and at an underwater distance of 6 m.

Underwater heavy bullet weighing 14.0 g with a detachable tray of underwater ammunition 308 Win. (7.62 × 51) with a total bullet weight of 16 g has the following parameters:

a) when firing from a barrel filled with water:

- initial speed V = 455 m / s and energy E = 1450 J;

- speed V = 380 m / s and energy E = 1010 J at an underwater distance of 4 m;

- speed V = 315 m / s and energy E = 695 J at an underwater distance of 8 m;

- speed V = 190 m / s and energy E = 250 J at an underwater distance of 19 m;

b) when shooting from a dry barrel into the water:

- initial speed V = 575 m / s and energy E = 2315 J;

- speed V = 480 m / s and energy E = 1610 J at an underwater distance of 4 m;

- speed V = 400 m / s and energy E = 1120 J at an underwater distance of 8 m;

- speed V = 190 m / s and energy E = 250 J at an underwater distance of 24 m.

These parameters show that when firing underwater ammunition of caliber 308 Win. (7.62 × 51) the claimed device increases the effective firing range by 25 - 30% and increases the bullet energy by 40 - 60% on the underwater trajectory.

Unlike the prototype, the claimed device allows you to select the type of ammunition in the submerged position and charge or reload the weapon underwater before firing, as well as install or remove the muzzle valve 3, which is necessary for spearfishing in the open sea. For example, when visibility in water is up to 5 m and shooting at small hunting objects, it is advisable to use less powerful underwater ammunition, since more powerful ammunition can significantly damage the hunting object and make it unsuitable for human consumption. When a large hunting object is found, you can quickly replace the magazine 6 with powerful ammunition.

The practice of spearfishing shows that it is preferable to be able to quickly replace the magazine 6 of small arms 5, which is usually consumed in 3-5 seconds of firing, than to use a device - a prototype with a controlled muzzle valve and squibs, which is advisable to use for automatic cannons and machine guns with large ammunition ...

Figure 2 shows a longitudinal section of the proposed device before firing in the water with a hunting self-loading carbine "Saiga-308-1" for ammunition of caliber 308 Win. (7.62 × 51) with detached stock and no standard muzzle brake.

The device for underwater shooting includes a small arms 5, which is shown in Fig. 1, and the casing 1 is also equipped with a flexible pressurization tube 16. This device has some differences from the device shown in Fig. 1.

The weapon 5 is fixed in the casing 1 by a pin 13 and a tightening threaded connection of the muzzle of the barrel with a bushing 21, in which a through hole (D) and gas outlet ports 22 are made. The bushing 21 is installed in the casing 1 and compresses an elastic sealing ring 24. This ensures a reliable fastening of the weapon 5 in the casing 1, as well as the symmetrical mating of the bore and the bore (D), closed by the multi-position muzzle valve 23.

The device is equipped with a partition 27 dividing the cavity 2 into two non-closed compartments (A) and (B). In this case, the first shot is possible at an angle of plus or minus 30 degrees to the horizon, since at these angles of inclination of the device, water does not penetrate into the barrel with automation units, and the partition 27 protects the gas outlet ports 22 from water penetration. The partition 27 increases the time for filling the cavity 2 with water when firing is stopped in comparison with the time indicated in the description of Fig. 1, increases the time for maintaining the increased pressure in the muzzle compartment (A) and allows you to shoot at increased depth with increased water pressure with a reduced rate of fire. In this case, the powder gas flowing out of the holes 17 of the gas tube, from the chamber of the weapon 5 during the extraction of the sleeve and flowing out of the compartment (A), creates an increased pressure in the compartment (B), which allows you to shoot at any angle to the horizon.

The diameter of the bore (D) is equal to 1.01 - 1.02 of the diameter of the rifled bore, measured along the rifling fields, which ensures stable guidance of the bullet in the bore (D) and crimping the outer surface of the bullet, while maintaining the angular velocity of rotation obtained in the barrel bullets and reduced bullet dispersion. The total side area of the gas outlet ports 22 is 4 to 6 times the cross-sectional area of the barrel bore, and the size (L) between the muzzle of the barrel and the muzzle end of the sleeve 21 is 6 to 12 barrel calibers. This provides the necessary expansion of the powder gas when it flows out through the gas outlet ports 22 into the compartments (A) and (B), which reduces the pressure of the powder gas flowing from the passage hole (D) into the water and eliminates an increase in hydraulic pressure in the area of the bullet entry into the water.

The multi-position muzzle valve 23 is made of a plastic material, for example, fluoroplastic F-4 and is made in the form of a flat strip, the width of which exceeds the diameter of the bore (D). In this case, the muzzle valve 23 is mated with the muzzle end of the sleeve 21 with the possibility of longitudinal movement relative to the bore (D) due to the elastic pressure of the annular flange 25 provided with tension springs 26.

In one embodiment, the muzzle valve 23 has two positions, where the first position closes the port (D) and the second position opens the port (D) before firing. In this case, the muzzle valve 23 can have a passage window for the passage of the bullet when fired. Before shooting, the shooter opens the port (D) by moving the muzzle valve to the second position and aligning the port of the muzzle valve 23 and the port (D). When firing stops, the shooter closes the passage hole (D) by moving the muzzle valve 23 to the first position. Taking into account the time of filling the cavity 2 with water, indicated in the description of Fig. 1, and the advantages of the partition 27, during the time of opening and closing the passage opening (D), the cavity 2 will be slightly filled with water, which will be removed during firing.

In another version, the multi-position muzzle valve 23 is shot through with a bullet at the beginning of firing, while a bullet hole is formed in it without cracks or burrs. At each stop of firing, the shooter moves the muzzle valve, displaces the bullet hole and closes the bore (D) with the clean muzzle valve surface. In this case, the muzzle valve 23 can be equipped with a handle and grooves for the convenience of its movement at each step at each stop of firing and for fixing it in a given position, for example, with a spring clip. This option avoids wasting time opening the port (D) before shooting and is preferable for spearfishing.

In addition, a multi-position muzzle valve made of a plastic material and shot by a bullet at the beginning of firing can be in the form of a flat ring, mated with the muzzle end of the sleeve 21, with the ability to rotate around its central axis to displace the bullet hole and close the passage hole with its clean surface ( D) when firing is stopped. In this case, the width of the flat ring, measured between its larger and smaller diameters, exceeds the diameter of the bore (D).

The principle of operation of the device Fig. 2 corresponds to the description of the device in Fig. 1, in addition to the design of the multi-position muzzle valve 23. In addition, the casing 1 may have outer plates 28 installed across the firing line, while each plate 28 will reduce the recoil of an underwater shot due to its braking water, which will allow you to hold the weapon with one hand.

Figure 3 shows a longitudinal section of the proposed device before firing in the water with an automatic rifle "NK 417" for ammunition of caliber 308 Win. (7.62 × 51) with standard flame arrester and detached stock.

The device for underwater shooting includes a casing 31 with an inner cavity 32 and a through hole (D), which is made in the bushing 46, is intended for the passage of a bullet when fired and is closed by the muzzle valve 33. A bottom window 34 is made in the lower wall of the casing 31. The barrel of the weapon 35 s flame arrester 37 and automation units, as well as the safety lever 39, the loading handle 40, the shutter stopper lever 41, the trigger 42 and the magazine latch 43 are located in the inner cavity 32. In this case, part of the weapon handle 35 and part of the magazine 36 with twenty ammunition protrude from the inner cavity 32. The device is provided with a partition 52 dividing the cavity 32 into two non-closed compartments (A) and (B), the advantage of which is presented in the description of Fig. 2. The width of the casing 31 and the bottom window 34 provide the ability to load the weapon 35, control the safety and firing mechanisms, including parts 39 to 43, extract the cartridge case and remove the ammunition from the chamber. In this case, the casing 31 can be made of two or more components for the convenience of attaching the weapon 35 and holding the handle of the weapon 35.

The weapon 35 is fixed in the casing 31 by a screw 44 screwed into the bottom of the aluminum tube 45 of the return spring, and the flame arrester 37 is tightly mated with the tapered surface (C) of the bushing 46, which is fastened by a tightening threaded connection to the nut 47, which is fixed in the casing 31. This ensures reliable fasten weapons 35 in the casing 31 and symmetrical mating of the bore with the bore (D). The muzzle valve 33, mounted on the axle 48 in the nut 47, is pressed by the torsion spring 49 against the muzzle end of the sleeve 46 and closes the passage hole (D) before firing. In this case, the device is equipped with an additional muzzle valve 50, which is mounted on an axis in a nut 47, compressed by a torsion spring 49 and fixed in the firing position by a groove of a stopper 51 at an angle of approximately 45 degrees from the firing line.

The materials of the casing 31, bushing 46, nut 47 and muzzle valves 33 and 50, as well as the diameter of the bore (D), the size between the muzzle end of the flame arrester 37 and the muzzle end of the sleeve 46 correspond to the materials and dimensions indicated in Fig. 1.

The dimensions of the casing 31 and the volume of the cavity 32 provide the device with the weapon 35 positive buoyancy. The increased height of the casing 31 relative to the casing 1 (Figs. 1 - 2) allows shooting at a depth of up to 12 m. In this case, the casing 31 can be equipped with a pressurization tube 16, the purpose of which is presented in the description of Fig. 1.

Preparation of the device for underwater shooting is carried out by lowering the device from air into the water with the bottom window 34 down. In this position, the air (mixture of gases) in the inner cavity 32 holds water at the level of the bottom window 34. When loading the weapon 35, the bolt is moved to the rear position by the loading handle 40, where the bolt is held by the bolt stopper. A magazine 36 with the selected type of ammunition is installed in the weapon 35. When you press the bolt stopper lever 41, the wet ammunition is sent by the bolt from the magazine 36 to the chamber of the weapon 35. Before firing, the safety lever 39 is moved to the firing position.

The first shot is possible at an angle of plus or minus thirty degrees to the horizon. At these angles of inclination of the device, water does not penetrate into the barrel with the automation units, and the partition 52 protects the gas outlet 38 from water penetration. In the event of water penetration into the return spring tube 45, the holes 54 allow water to escape when the valve moves. The shot occurs when the trigger 42 is pressed. When fired, the underwater bullet destroys the muzzle valve 33 and enters the water, and the propellant gas flowing into the through hole (D) forms a gas bubble in front of the muzzle end of the sleeve 46, which prevents water from entering the through hole ( D). The propellant gas flowing out of the vent ports 38 accumulates in the compartment (A) and maintains an overpressure in the vent ports 38 and the orifice (D). Powder gas flowing out of the opening 55 of the gas chamber, from the chamber of the weapon 35 during the extraction of the cartridge case and flowing out of the compartment (A) creates an increased pressure in the compartment (B). In this case, the pressure of the powder gas in the gas bubble created in front of the muzzle end of the sleeve 46 turns the additional muzzle valve 50 away from the firing line, and it comes out of the stopper slot 51. But at this moment, the muzzle valve 50 cannot close the bore (D), since the force of the torsion spring 49 is prevented by the pressure of the gas bubble. The pressure of the propellant gas in the compartments (A) and (B), which prevents water from entering the passage opening (D) and the bottom window 34, is maintained for about one second. At this second, a second shot can be fired, and the next second - a third shot, namely, you need to shoot at a rate of one shot per second or 60 rounds per minute in semi-automatic shooting. In this case, the pressure of the powder gas in the sections (A) and (B) allows you to shoot at any angle to the horizon. With automatic firing with a rate of fire of 600 rounds per minute, you can use up the entire magazine (20 ammunition) in 2 seconds of firing, and sending wet ammunition from magazine 36 into the chamber of weapon 35 will cool the barrel in this mode of fire.

After stopping firing and equalizing the pressure of the gas mixture in compartments (A) and (B) with external water pressure, an additional muzzle valve 50, under the action of a torsion spring 49, closes the passage opening (D). By pressing the magazine latch 43, an empty magazine is removed and a magazine 36 with ammunition is installed. The bolt is moved to the rear position by the loading handle 40, where it is held by the bolt stop. When you press the shutter stopper lever 41, the wet ammunition is sent by the shutter from the magazine 36 to the chamber of the weapon 35 and the weapon is ready for firing.

In addition to muzzle valve 33 and additional valve 50, four additional muzzle valves can be installed. In this case, the sleeve 46 will have six muzzle valves installed around the port (D). In this case, the muzzle valve 33 will close the passage opening (D) before the first firing, and the additional muzzle valve 50, installed in the firing position, will close the passage opening (D) when the first firing is stopped. The other four additional muzzle valves will be fixed in the slots 53 of their stoppers 51 perpendicular to the firing line, where the pressure of the propellant gas in the gas bubble formed in front of the muzzle end of the sleeve 46 will not affect them. After the use of the additional muzzle valve 50, these four additional muzzle valves will be sequentially transferred to the firing position.

After all muzzle valves have been used, new muzzle valves must be installed to continue firing underwater. However, it is possible to continue shooting with a quick change of the magazine 36, taking into account the time of filling the inner cavity with water when the firing is stopped, as indicated in the description of Fig. 1, especially when repelling the attack of sea predators, when there is no time and chance to replace the muzzle valves. Therefore, in the event of a probable attack by sea predators, it is advisable to use the "Beta C-Mag" double-drum magazine with a capacity of 100 ammunition, and sending wet ammunition into the chamber allows for any firing mode.

In this case, the device can be equipped with a laser designator and / or a mechanical sight for aiming the weapon at the target. This increases the efficiency of using the proposed device.

In addition, the device can be installed in a mount with the ability to rotate horizontally and vertically. This increases the safety of using the proposed device for training shooting.

Figure 4 shows a longitudinal section of the proposed device with a semi-automatic rifle "LMT-Piston" for ammunition 223 Remington (5.56 × 45) without a standard flame arrester.

The device for underwater shooting includes a casing 61 with an internal cavity 62 and a through hole (D), which is made in the bushing 63 and is designed to fly a bullet when fired. A bottom window 64 is made in the lower wall of the casing 61. The barrel of the weapon 65 with the automation units, as well as the bolt rammer 66, the loading handle 67 and the bolt stopper lever 68 are located in the inner cavity 62. The safety lever 69, the trigger 70, the magazine latch 71, the grip of the weapon 72, the magazine 73 with thirty ammunition and the stock stopper lever 74 protrude from the inner cavity 62. The device is equipped with a muzzle chamber 75 with a front wall 76 and a rear wall 77 dividing the cavity 62 into two non-closed compartments (A) and (B ), the advantage of which is presented in the description of Fig. 2.

The weapon 65 is fastened to the front wall 76 of the muzzle chamber 75 by a tightened threaded connection of the muzzle of the barrel with the bushing 63, in which the gas outlet 78 are made, and the stock 79 is rigidly attached to the rear wall of the casing 61. This ensures reliable fastening of the weapon 65 in the muzzle chamber 75 and in casing 61, symmetrical mating of the barrel bore and the bore (D) and the possibility of telescopic movement of the casing 61 relative to the muzzle chamber 75 when adjusting the length of the butt 79 using the butt stopper lever 74. The width of the casing 61 and the bottom window 64 provide the ability to load the weapon 65, control the safety and firing mechanisms, including parts 66 - 68, cartridge case extraction and ammunition extraction from the chamber. In this case, the casing 61 can be made of two or more components for the convenience of attaching the weapon 65 and the muzzle chamber 75. The casing 61 and the muzzle chamber 75 are made of impact-resistant plastic or aluminum alloy, and the bushing 63 is made of steel

The diameter of the bore (D) is equal to 1.01 - 1.02 of the diameter of the rifled bore, measured along the rifling fields, which provides stable guidance of the bullet in the bore (D) and crimping the outer surface of the bullet, while maintaining the angular velocity of rotation of the bullet obtained in the barrel, and the dispersion of bullets is reduced. The total lateral area of the gas outlet ports 78 is 4 to 6 times the cross-sectional area of the barrel bore, and the size (L) between the muzzle of the barrel and the muzzle end of the sleeve 63 is 6 to 12 barrel calibers. This provides the necessary expansion of the propellant gas when it flows through the gas outlet ports 78 into the cavity 62, namely, into the compartment (A), which reduces the pressure of the propellant gas flowing from the through hole (D) into the water and eliminates an increase in the hydraulic pressure in the bullet entry zone in water.

To increase the safety of underwater shooting from small arms, the device uses underwater ammunition, and there is no muzzle valve.

Preparation of the device for underwater shooting is carried out by lowering the device from air into water and filling the cavity 62 and weapon 65 with water. When loading the weapon 65, the bolt is moved to the rear position by the loading handle 67, where the bolt is held by the bolt stopper. A magazine 73 with the selected type of ammunition is installed in the weapon 65. When you press the bolt stopper lever 68, the wet ammunition is sent by the bolt from the magazine 73 to the chamber of the weapon 65. Before firing, the safety lever 69 is moved to the firing position.

The shot takes place when the trigger 70 is pressed. When fired, the powder gas pushes water out of the barrel bore and automatic units of the weapon 65, the bullet enters the water, and the powder gas flowing out into the passage hole (D) forms a gas bubble in front of the muzzle end of the sleeve 63, which prevents water from entering the port (D). The propellant gas escaping from the vent ports 78 accumulates in the compartment (A) and maintains an overpressure in the vent ports 78 and the orifice (D). Powder gas flowing out of the hole 80 of the gas chamber, from the chamber of the weapon 65 during the extraction of the sleeve and flowing out of the compartment (A) creates an increased pressure in the compartment (B). The pressure of the propellant gas in the compartments (A) and (B), preventing the penetration of water into the passage opening (D) and the bottom window 64, remains for about one second. At this second, a second shot can be fired, and the next second - a third shot, namely, you need to shoot at a rate of one shot per second or 60 shots per minute with semi-automatic shooting. In this case, the pressure of the powder gas in the sections (A) and (B) allows you to shoot at any angle to the horizon.

When firing stops and the pressure of the propellant gas in the cavity 62 is equalized with external water pressure, water begins to fill the cavity 62 through the bottom window 64 and squeeze the propellant gas into the passage hole (D), the bubbles of which prevent water from entering the passage hole (D). The time for filling the cavity 62 with water depends on the flow rate of the propellant gas through the passage hole (D) and on the volume of the cavity 62. In the device shown in Fig. 4, the time for the rise of water from the bottom window 64 to the level of the barrel is three seconds. This means that taking into account the time of the increased pressure in cavity 62 after the shot, you can wait four seconds and fire from a dry barrel, while the powder gas will remove all water from cavity 62, so you can wait another four seconds and shoot again, etc. This means that the claimed device shown in Fig. 4 allows you to use up the entire magazine 73 at a rate of fire of at least 15 rounds per minute, which allows you to calmly aim with each shot, for example, when shooting sports in "Aquatira". Moreover, within four seconds, you can replace the store 73 and continue shooting.

As the time between shots increases (more than four seconds), cavity 62 and weapon 65 are filled with water, which is removed by the first shot in the next series of shots. At the same time, the parameters of the first bullet in a series of shots correspond to those of a bullet when firing from a water-filled small arms barrel, but the parameters of the next bullets in a series of shots fired from a dry barrel are approximately equal to the parameters of ammunition bullets intended for firing from air into water.

For example, an underwater bullet weighing 5.3 g underwater ammunition 223 Remington (5.56 × 45) has the following parameters:

a) when firing from a barrel filled with water:

- initial speed V = 510 m / s and energy E = 690 J;

- speed V = 255 m / s and energy E = 170 J at an underwater distance of 4 m;

- speed V = 180 m / s and energy E = 85 J and at an underwater distance of 6 m.

At the same time, the practice of spearfishing shows that a 5.56 mm underwater bullet with an energy of approximately E = 85 J can ensure the defeat of a hunting object weighing up to 30 kg.

b) when shooting from a dry barrel into the water:

- initial speed V = 650 m / s and energy E = 1120 J;

- speed V = 325 m / s and energy E = 280 J at an underwater distance of 4 m;

- speed V = 180 m / s and energy E = 85 J and at an underwater distance of 7.5 m.

An underwater bullet weighing 5.5 g with a detachable tray of underwater ammunition 223 Remington (5.56 × 45) with a total mass of 6.4 g of a bullet has the following parameters:

a) when firing from a barrel filled with water:

- initial speed V = 470 m / s and energy E = 610 J;

- speed V = 330 m / s and energy E = 300 J at an underwater distance of 4 m;

- speed V = 230 m / s and energy E = 145 J at an underwater distance of 8 m;

- speed V = 175 m / s and energy E = 85 J at an underwater distance of 11 m;

b) when shooting from a dry barrel into the water:

- initial speed V = 590 m / s and energy E = 960 J;

- speed V = 415 m / s and energy E = 470 J at an underwater distance of 4 m;

- speed V = 290 m / s and energy E = 230 J at an underwater distance of 8 m;

- speed V = 170 m / s and energy E = 80 J at an underwater distance of 14 m.

These parameters show that when firing underwater ammunition of caliber 223 Remington (5.56 × 45), the claimed device increases the bullet energy on the underwater trajectory by 50-60% and increases the effective firing range by 25-30%.

If desired, you can install a muzzle valve in the sleeve 63, and for firing use ammunition intended for firing from air into water, as indicated in the description of Figs. 1 - 3. This will increase the energy of the bullet on the underwater trajectory and the effective firing range.

For example, an underwater bullet weighing 5.3 g of ammunition 223 Remington (5.56 × 45) for firing from air into water has the following parameters:

- initial speed V = 750 m / s and energy E = 1490 J;

- speed V = 375 m / s and energy E = 370 J at an underwater distance of 4 m;

- speed V = 190 m / s and energy E = 95 J and at an underwater distance of 8 m.

An underwater bullet weighing 5.5 g with a detachable ammunition pan 223 Remington (5.56 × 45) for firing from air into water with a total projectile mass of 6.4 g of a bullet has the following parameters:

- initial speed V = 685 m / s and energy E = 1290 J;

- speed V = 480 m / s and energy E = 630 J at an underwater distance of 4 m;

- speed V = 180 m / s and energy E = 90 J and at an underwater distance of 15 m.

These parameters show that when firing 223 Remington (5.56 × 45) ammunition designed for firing from air into water, the claimed device doubles the bullet energy on the underwater trajectory and increases the effective firing range by 35% compared to the parameters of underwater bullets. ammunition when firing from a water-filled small arms barrel.

Claims (14)

1. A device for underwater shooting from small arms, including small arms with ammunition, a casing with an internal cavity and a passage hole, which is designed for the passage of a bullet when fired and closed by a muzzle valve before firing, characterized in that at least one bottom window for loading small arms with ammunition and for controlling the safety and firing mechanisms of small arms, while at least a barrel with small arms automation units is placed in the inner cavity of the casing. 2. The device according to claim 1, characterized in that the casing is provided with pressurizing means for supplying a mixture of gases into the inner cavity of the casing. 3. The device according to claim 1, characterized in that the passage hole is made in a bushing fixed in the casing and mated with the muzzle of the weapon barrel, which has gas outlet ports for the outflow of powder gas from the muzzle of the weapon barrel into the inner cavity of the casing. 4. The device according to claim 1, characterized in that the passage hole is made in a bushing fixed in the casing and mated with the muzzle of the weapon barrel, wherein the bushing is provided with gas outlet ports for the outflow of powder gas from the bushing into the inner cavity of the casing. 5. The device according to claim 1, characterized in that the muzzle valve is made of a brittle plastic capable of breaking into fragments when it is shot by a bullet. 6. The device according to claim 5, characterized in that it is equipped with at least one additional muzzle valve that closes the passage opening when firing is stopped. 7. The device according to claim 1, characterized in that the muzzle valve has at least two positions and is mated with the muzzle end of the sleeve with the possibility of longitudinal movement to open the passageway before firing and to close the passageway when firing is stopped. 8. The device according to claim 1, characterized in that the muzzle valve is made of a plastic material in which a bullet hole is formed when it is shot by a bullet. 9. The device according to claim 8, characterized in that the muzzle valve has at least two positions and is mated with the muzzle end of the sleeve with the possibility of longitudinal movement to close the passage opening with its clean surface when firing is stopped. 10. The device according to claim 1, characterized in that it is provided with at least one partition dividing the internal cavity into open compartments. 11. A device for underwater shooting from small arms, including small arms with ammunition, a casing with an internal cavity and a through hole, which is intended for the passage of a bullet when fired, characterized in that at least one bottom window is made in the lower wall of the casing for loading small arms weapons with ammunition and to control the safety and firing mechanisms of small arms, while at least a barrel with small arms automation units is placed in the inner cavity of the casing, and underwater ammunition with an underwater bullet intended for firing in water is used for firing. 12. The device according to claim 11, characterized in that the through hole is made in a sleeve fixed in the casing and mated with the muzzle of the weapon barrel, which has gas outlet ports for the outflow of powder gas from the muzzle of the weapon barrel into the inner cavity of the casing. 13. The device according to claim 11, characterized in that the through hole is made in a bushing fixed in the casing and mated with the muzzle of the weapon barrel, wherein the bushing is provided with gas outlet ports for the outflow of powder gas from the bushing into the inner cavity of the casing. 14. The device according to claim 11, characterized in that it is provided with at least one partition dividing the internal cavity into open compartments.

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