RU2650261C1 - Device for controlled dispersion of the bullets of the multi-bullet cartridge (variants) - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: group of inventions refers to the field of weapons, namely to devices for the controlled dispersion of the bullets of a multi-bullet cartridge. Device for the controlled dispersion of the bullets of the multi-bullet cartridge contains the barrel of the weapon. According to a first embodiment, the barrel of the weapon has, in the vicinity of the muzzle, two or more lateral outlets that are connected by a gas channel with an annular nozzle disposed around the barrel, or with several individual nozzles, located around the barrel. According to a second embodiment, the device is two protrusions protruding beyond the barrel of the barrel, having inside two gas channels connected to the bore of the barrel, and on the protrusions there are one or more slit or circular nozzles directed towards each other, towards each other and further forward in the direction of the shot, tangential to the axis of the trunk, tangentially to the axis of the barrel and further forward in the direction of the shot.

EFFECT: regulation of the cone of scattering of multiple shot elements is achieved.

13 cl, 4 dwg

Description

The invention relates to small arms and firearms.

Known types of small arms, such as US Pat. No. 2513886, and tools are known, for example US Pat. No. 2477434. Mostly both of them shoot a monolithic body - a bullet or a shell. But hunting rifles firing shots are known, and guns firing buckshots are known. Moreover, the "Multi-element Staroverov cartridge (options)" is known. No. 2462685, shooting with feathered arrows.

The disadvantage of these known types of weapons is the impossibility of regulating the dispersion cone of multiple elements of the shot, and even more so - giving this cone the desired asymmetry.

The objective and technical result of the invention is the regulation of the dispersion cone of multiple elements of the shot, as well as giving this cone the desired asymmetry, as well as the operational change of this cone.

Close analogues to this invention are not known.

The invention can be used on machine guns, machine guns and on guns of all calibers, especially 30-mm guns for firing at nearby infantry (up to 500 meters, depending on the caliber of the arrows). The barrel is desirable smoothbore, but acceptable and rifled.

OPTION 1. In order to make the dispersion cone (hereinafter “cone”) wider, and possibly narrower, it is possible to direct a beam of multiple elements (hereinafter “elements”) just emerging from the muzzle from an annular nozzle or from several separate circular or rectangular nozzles arranged in a ring, the flow of powder gases, suitably oriented.

To do this, the barrel of the weapon has two or more outgoing lateral branches inside the barrel, which are connected by a gas channel with an annular nozzle located around the barrel, or with several separate nozzles located around the barrel.

The simplest device may be unregulated.

But in order to be able to direct more or less powder gases into the indicated annular nozzle and thereby control the degree of impact on the cone, the device may have shut-off and control devices of any design in the gas channel. These can be on-off devices of the “closed-open” type, or they can be devices that smoothly or step-by-step change the passage section of the gas channel between the bends in the barrel and the nozzle / nozzles.

For example, it can be a threaded sleeve mounted on the thread at the end of the barrel, and between the sleeve and the barrel there remains a longitudinal annular channel located in the body of the sleeve or in the body of the barrel, which can overlap when the sleeve is rotated. Both designs are approximately equivalent in functional properties, but the design, when the channel is located in the barrel’s body is somewhat easier technologically (no internal boring is required, no complicated barrel processing is required) and has a slightly smaller overall diameter.

Since the sleeve is washed by powder gases, it will become very hot. Therefore, there are cooling fins on it. To rotate the hot sleeve by hand, the sleeve has a molded (glued, vulcanized, jointly polymerized) ring of low heat conductive and heat-resistant material (heat-resistant plastic). And in case the sleeve "sticks" to the barrel, the sleeve has a hexagon for the standard size of a wrench.

To control the dispersion cone, in this design, powder gases can be directed in five different ways.

1. Parallel to the bore (hereinafter, all directions are given relative to the direction of the shot). In this case, the gases will flow around the beam of elements from the outside at a higher speed than they fly, and therefore there will be a suction force that will pull the outer layers of the beam to the periphery. It is difficult to theoretically predict the strength of the resulting effect, so a series of experiments is required.

2. Powder gases can be directed to the axis of the barrel. In this case, it is difficult to predict not only the strength of the resulting effect, but even its direction. It is possible that at a small angle to the axis of the barrel there will be a narrowing of the cone of the elements (the effect of the barrel “pay” in the hunting rifle), and with a large angle of inclination, on the contrary, the cone of the elements will expand.

3. Powder gases can be directed from the axis of the barrel. In this case, the most likely expansion of the cone of elements.

4. Powder gases can be directed tangentially forward to the axis of the barrel (as if in a spiral). In this case, the expansion of the cone of the elements will probably be observed, since the outer layers in the bundle of elements will be blown tangentially away from the longitudinal axis of the barrel.

5. Powder gases can be directed by any of the above methods, but asymmetrically, that is, not around the entire perimeter of the barrel muzzle. For example, to the soybean trunk in sectors above 60 degrees and below 60 degrees (when viewed from the front). In this case, the beam will take the form of a cone flattened from above and below, which on the target will give a shape similar to a horizontal line from an automaton (or maybe a vertical, reliable result will be given only by experiments).

In FIG. 1, 2 show in cross section two sub-options of the first variant of the weapon. In FIG. 1, the gas channel is located in the body of the sleeve, and in FIG. 2 - in the body of the trunk.

In both sketches: 1 - the trunk (in Fig. 2, the barrel at the barrel has an increase in diameter so that the section at the barrel does not turn out to be too thin), 2 - taps from the barrel, 3 - a threaded sleeve. The barrel has an annular nozzle 4 around the barrel located in the barrel body (in FIG. 1) or formed by a gap between the barrel and the sleeve (FIG. 2). There are cooling fins 5 on the sleeve, there is a plastic ring pad 6 for rotation with bare hands, and there is a hexagon 7 for the standard size of a wrench. The thread should rotate with some effort or should have a thread stopper (sleeve spontaneous rotation stopper). The latter is not shown, but can have any traditional design, for example, a spring-loaded peg or a ball on the sleeve, which is included in the longitudinal grooves on the outer surface of the barrel.

The device works as follows: when fired, part of the powder gases is discharged into the side bends 2 of the barrel 1, and then through the gas channel the gases enter the annular nozzle or several nozzles 4 located in a ring around the barrel. Both sketches show the complete opening of the gas channel between the barrel 1 and the sleeve 3 and shows the nozzle 4 direction parallel to the barrel channel. But the direction can be different, see the five methods described above.

The adjustment of the quantity of powder gases is carried out by displacing the sleeve 3 by rotating it along the thread. Moreover, in FIG. 2, a decrease in gas flow occurs when the sleeve is shifted forward, and when the sleeve is shifted back. In FIG. 2, when the sleeve is shifted back, the consumption of powder gases decreases, and then closes.

OPTION 2. In the previous embodiment, the gases from the nozzle / nozzles were directed mainly forward with a deviation in the right direction. But if very wide dispersion is required, then it is more efficient to direct the powder gases from both sides across or across the front of the direction of departure of the elements. Moreover, two methods are possible here: either the jets of gases are directed towards each other (approximately, as in method 5 described above), or tangentially from two sides (approximately, as in method 4). In the first case, the beam of elements is compressed from two sides, and the cone is as if flattened, and in the second case, one half of the beam is drifted to one side (say, to the right), and the second half is drifted to the opposite side (to the left). In any case, you get the effect of a machine gun queue.

Such a device consists of two protrusions protruding beyond the muzzle, having two gas channels inside, connected to the barrel channel, and on the protrusions there are one or more slotted or round nozzles directed towards, towards, forward, tangentially or tangentially forward.

The device according to this option, as in the first embodiment, can be stationary, that is, stationary relative to the barrel, and can be mounted on the barrel with the ability to rotate - the easiest way to thread. And just like in the first embodiment, it can have a locking and regulating device. For example, the threaded sleeve described above, forming an adjustable gas channel with the barrel. That is, the same sleeve, but with protrusions beyond the muzzle.

The simplest device according to the second embodiment consists of two deaf nozzles welded to the barrel, connected to the bore, having each nozzle / nozzles, and the sealed rods that can be controlled to move back and forth (for example, on the thread) enter the nozzles at the back.

In FIG. 3, 4 are shown in two projections - in cross section and in front view.

The device comprises: a barrel 1, two welded nozzles 8, connected to the barrel channel by two taps 2, and two rods 9, entering the rear of the nozzles.

The nozzles in front of the barrel have nozzles 4.

This device works as follows: when fired, part of the powder gases rushes into the bends 2 and then through the nozzles into nozzles 4 directed one of the four methods described above. The direction of the jets in FIG. 4 is shown by arrows.

Moving the rods 9 back and forth (a large force acts on them), you can adjust the amount of powder gases or completely lock the nozzles.

Applying the invention in conjunction with the aforementioned US Pat. No. 2462685, it is possible, for example, from a 12.7 mm machine gun in one shot to fire 7 arrows with a diameter of 4.23 mm, and another wad (which, however, flies nearby). And from a 30-mm cannon in one shot, you can fire a whole “turn” of 19 or 38 (in two transverse rows) arrows with distorted geometry with a diameter of 6 mm or 37 or 74 arrows with a diameter of 4.28 mm. And with a high initial speed.

Claims (13)

1. A device for controlled dispersion of bullets of a multi-bullet cartridge containing a weapon barrel, characterized in that the weapon barrel has two or more outgoing lateral outlets in the vicinity of the barrel, which are connected by a gas channel with an annular nozzle located around the barrel, or with several separate nozzles located around dula. 2. The device according to claim 1, characterized in that the device has a locking-regulating device in the gas channel. 3. The device according to p. 2, characterized in that the locking and regulating device is a threaded sleeve, mounted on the thread at the end of the barrel, and between the sleeve and the barrel there remains a longitudinal annular channel located in the body of the sleeve or in the body of the barrel, which can overlap when rotating the sleeve. 4. The device according to claim 3, characterized in that there are cooling fins on the sleeve, there is a molded ring of low heat conductive and heat-resistant material, the sleeve has a hexagon for the standard size of a wrench and, possibly, a thread stopper. 5. The device according to p. 1, characterized in that the powder gases are directed parallel to the bore. 6. The device according to p. 1, characterized in that the powder gases are directed to the axis of the barrel. 7. The device according to claim 1, characterized in that the powder gases are directed from the axis of the barrel. 8. The device according to p. 1, characterized in that the powder gases are directed tangentially forward to the axis of the barrel. 9. The device according to claim 1, characterized in that the powder gases are not directed along the entire perimeter of the barrel muzzle. 10. A device for controlled dispersion of bullets of a multi-bullet cartridge containing a weapon barrel, characterized in that it consists of two protrusions protruding beyond the muzzle, having two gas channels inside connected to the barrel channel, and on the protrusions there are one or more slot or circular nozzles, directed towards each other, towards each other and further forward in the direction of the shot, tangentially to the axis of the barrel, tangentially to the axis of the barrel and further forward in the direction of the shot. 11. The device according to p. 10, characterized in that it has a locking-regulating device in the gas channel. 12. The device according to p. 10, characterized in that the protrusions are located on a threaded sleeve, mounted on the end of the barrel on the thread. 13. The device according to p. 10, characterized in that it consists of two blind pipe welded to the barrel, connected to the bore, having each nozzle / nozzles, and sealed rods that can be controlled to move back and forth into the pipes.

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