RU2646149C1 - Manual grenade (options) - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: invention relates to hand grenades. Novelty is the garnet has the form of a cylinder with a diameter to height of not less than 1.5, contains a cylindrical or barrel-like or coil-shaped fragmentation element (hereinafter a "cylinder") or several coaxially located elements in which there is/are an explosive charge occupying the entire internal volume of the cylinder or located at the middle of its height, besides the fuse is located on the cylindrical side of the grenade.

EFFECT: charge EM in the form of a disk can be located freely inside the cylinder, in this case, when the grenade falls to the ground, it occupies the lower position, providing a better distribution of the fragments.

12 cl, 2 dwg

Description

The invention relates to hand grenades.

Grenades are known, for example, RGO and RGN, see Internet, or grenade according to US Pat. No. 75026.

A disadvantage of known grenades is the non-optimal distribution of fragments in space - they scatter almost evenly in a spherical direction. Conditionally a disadvantage can be considered different weight identical in design and size of grenades RGO and RGN. Having developed a specific tactile-reflex muscular reaction to one type of grenade during training (as the soldiers say, “stuffing your hand”), a soldier may make a mistake by picking up a lighter or heavier grenade and not hit the target. The factor that, due to its lower weight, an offensive grenade can be thrown 5 meters further, cannot be considered decisive. More important is the stable throw accuracy developed by the soldiers if the grenades are the same weight.

The objective and technical result of the invention is the expansion of fragments in the optimal sector of destruction and the same weight of different types of grenades.

OPTION 1. For this, the grenade has the form of a cylinder with a diameter to height ratio of at least 1.5, contains a cylindrical, or barrel-shaped, or reel-shaped fragmentation element (hereinafter referred to as the “cylinder”) or several such elements coaxially located inside which there is an explosive charge ( further BB), occupying the entire internal volume of the cylinder or located in the middle of its height, and the fuse is located on the cylindrical side of the grenade.

An explosive may not occupy the entire volume of the cylinder if the initial velocity of the fragments is considered excessive (especially relevant for offensive grenades).

The optimal shape of the fragmentation element (cylindrical, reel, barrel-shaped) should be determined experimentally. A barrel-shaped form is considered to be close to the cylinder, but with a narrowing at the ends. A reel is considered to be a shape close to the cylinder, but with a narrowing in the middle of the height of the cylinder.

A grenade can have one fragmentation element (for example, a defensive one) or two concentric thinner elements containing smaller fragments (offensive version) having the same total mass as one in a defensive grenade. That is, the offensive and defensive grenades will have the same mass, which will make it easier for soldiers to "get their hands on."

So that the grenade after the throw does not occupy the “on the edge” position, the grenade has a protrusion on the cylindrical surface.

So that the grenade does not roll over the surface after the throw, the fuse is located radially on its cylindrical surface and protrudes beyond it. That is, when trying to roll, a grenade stumbles upon a protruding fuse to the surface and falls on its side.

The fuse may be located on the cylindrical surface radially, or, to break the symmetry during rolling, it may be located obliquely to the axis of the cylinder.

The fragmentation-forming relief on the cylinder can be obtained on the outer and / or on the inner surface of the cylinder during casting (the inner surface of the cylinder is thus processed by scanning to a predetermined diameter). And it can be obtained jointly by casting on the outer surface and by applying longitudinal, transverse or inclined grooves on the inner surface of the cylinder.

To quickly reduce the speed of fragments in the atmosphere (which is especially important for offensive grenades) and to enhance the damaging effect of fragments, the fragmentation element can be made of sodium, potassium, sodium-potassium or sodium-potassium-magnesium alloy. When it enters the body, such fragments begin to react with blood, causing severe damage to living tissues by the alkali formed.

Can be considered an image of this grenade of FIG. 1 or FIG. 2 provided that the explosive charge, pos. 3, is located in the middle of the height of cylinder 2.

The grenade works like this: after falling to the ground due to a flat shape resembling a hockey puck, the grenade tends to end up parallel to the ground. In this case, the fragmentation element will be directed to the sides, and the expansion of the fragments will be directed in all directions horizontally and in the vertical sector approximately ± 15 degrees from the horizontal. Such a sector can be considered almost optimal for defeating both the running and the lying manpower of the enemy.

OPTION 2. However, in the previous case, almost half of the fragments will be directed to the surface. If the surface is hard and smooth, such as asphalt, then these fragments will ricochet and also hit the enemy. But if it is soft soil, then the fragments burrow into it and will not give the expected effect.

The second version of the grenade is free from this drawback. The grenade has the form of a cylinder with a ratio of diameter to height of at least 1.5, contains a cylindrical, or barrel-shaped, or reel-shaped fragmentation element (hereinafter referred to as the “cylinder”) or several elements coaxially located inside of which there is an explosive charge located with a gap in in the form of a cylindrical disk (strictly speaking, it is also a cylinder, since it has a thickness, but in order not to confuse this cylinder with the “cylinder” mentioned above, it will be called a “disk”), which occupies a part of the internal volume of qil NDRA, and the fuse is located on the cylindrical side of the grenade.

With sufficient mechanical strength, the explosive disc can be molded directly from it. But, taking into account the overloads acting on the disk when a grenade falls, the explosive charge can be located in a disk case made of more durable material (steel, plastic).

Disks with a large diameter to height ratio tend to jam in the cylinder surrounding them, so the gap between the explosive disk and the cylinder should be either greater than the difference between the spatial diagonal of the cylindrical disk and the minimum internal diameter of the cylinder, or less than half of this difference. In the first case, the disk does not jam even when its oblique position. And in the second case, the disc will not turn into a “too oblique” position and therefore will not jam if the surfaces of the disc and cylinder are of good quality. Here, by the “spatial diagonal” of a cylindrical disk is meant the hypotenuse of a right triangle, where the legs are the thickness and diameter of the disk.

Since there is a gap between the explosive and the fuse in this version, you should make sure that the fuse is guaranteed to cause detonation of the explosive. Otherwise, the following constructive measures can be taken. First, you can position the fuse with a protrusion in the inner space of the cylinder, and in the cylindrical disk to make a longitudinal groove for this part of the fuse.

Or, secondly, you can make the initiating explosive charge in the fuse in the form of a small cumulative charge, with or without a lining.

The fulfillment of the above conditions for the equality of masses of the offensive and defensive grenades in this variant varies somewhat, since the mass of explosives can be varied within small limits. That is, the grenade in the offensive version has a fragmentation element / elements and explosive charge, the total mass of which is equal to the mass of the fragmentation element / elements and explosive charge in the defensive version. That is, in order to impart increased destructive force to smaller fragments, the mass of the fragmentation element can be reduced, and the explosive charge can be increased if desired.

Of course, as in option 1, the grenade can have a protrusion along the cylindrical surface, and the fuse can be located radially or inclined to the axis of the cylinder.

In FIG. 1, 2 shows a grenade according to the second embodiment, it consists of a closed thin-walled steel casing 1, inside which there is a fragmentation element in the form of a segment of a regular round cylinder (more precisely, a pipe) 2, inside of which with a small gap there is a cylindrical disk 3 made of thin-walled steel, filled BB The height of the disk is significantly less than the height of the cylinder 2. On the outer surface of the grenade body there is an annular protrusion 4, which prevents the grenade from stopping on the rib. A fuse 5 with a retarding action (not shock type) is screwed into the hole in the cylinder 2.

The grenade in FIG. 1 of the defensive type, and in FIG. 2 - offensive type, it has a thinner cylinder and a larger number of explosives. The masses of pomegranates are the same.

Under the condition of the same outer diameter of the grenades and the same fuse length, two grenades in FIG. 1 and 2 have a subtle external difference - since the fuse in FIG. 1 penetrates deeper into the body of the grenade, its protruding outward part is somewhat smaller than in FIG. 2.

The grenade works according to the second variant as follows: when the grenade falls and stops, it lies flat on the ground, and the disk 3 inside it moves down due to gravity, and therefore the explosive detonates in the lower part of the fragmentation cylinder 2. As a result, the sector of fragmentation expansion compared to the first option shifts up and is approximately 0-30 degrees to the horizontal. With this sector of expansion, 100% of the fragments scatter in the sector of the possible presence of enemy manpower. That is, the effectiveness of the grenade is maximum.

OPTION 3. A simplified version of the grenade according to option 2 is possible - if the explosive is loose or liquid, then the grenade has the form of a cylinder with a diameter to height ratio of at least 1.5, contains a cylindrical, or barrel-shaped, or reel-shaped fragmentation element (hereinafter “cylinder”) or several coaxially located such elements, inside of which / which there is a free-flowing or liquid explosive, occupying part of the internal volume of the cylinder, the fuse being located on the cylindrical side of the grenade.

The grenade works in the same way as in option 2.

Claims (12)

1. A hand grenade containing a body and explosive charge, characterized in that it has the shape of a cylinder with a diameter to height ratio of at least 1.5, contains a cylindrical, or barrel-shaped, or reel-shaped fragmentation element (hereinafter “cylinder”) or several coaxially arranged such elements, within which / which there is an explosive charge, occupying the entire internal volume of the cylinder or located in the middle of its height, and the fuse is located on the cylindrical side of the grenade. 2. The grenade according to claim 1, characterized in that in the offensive version has a greater number of fragmentation elements, the total mass of which is equal to the mass of fragmentation elements in the defensive version. 3. The grenade according to claim 1, characterized in that it has a protrusion on the cylindrical surface. 4. Grenade according to claim 1, characterized in that the fuse is located on a cylindrical surface radially or inclined to the axis of the cylinder. 5. Grenade according to claim 1, characterized in that the fragmentation relief on the cylinder is obtained jointly by casting on the outer surface and applying longitudinal, transverse or inclined grooves on the inner surface of the cylinder. 6. The grenade according to claim 1, characterized in that the fragmentation element is made of sodium or potassium or sodium-potassium or sodium-potassium-magnesium alloy. 7. A hand grenade containing a body and explosive charge (hereinafter BB), characterized in that it has the form of a cylinder with a diameter to height ratio of at least 1.5, contains a cylindrical, or barrel-shaped, or reel-shaped fragmentation element (hereinafter “cylinder”) or several coaxially located such elements, within which / which there is a charge of an explosive located with a gap in the form of a cylindrical disk, occupying part of the internal volume of the cylinder, the fuse being located on the cylindrical side e grenades. 8. Grenade according to claim 7, characterized in that the explosive charge is located in a disk casing of a more durable material than an explosive. 9. Grenade according to claim 7, characterized in that the fuse is located with a protrusion in the inner space of the cylinder, and in the cylindrical disk there is a longitudinal groove for this part of the fuse. 10. Grenade according to claim 7, characterized in that the charge of the initiating explosive in the fuse is made in the form of a cumulative charge with or without a lining. 11. Grenade according to claim 7, characterized in that in the offensive version has a fragmentation element / elements and explosive charge, the total mass of which is equal to the mass of fragmentation element / elements and explosive charge in a defensive form. 12. A hand grenade containing a body and explosive charge (hereinafter BB), characterized in that it has the form of a cylinder with a diameter to height ratio of at least 1.5, contains a cylindrical, or barrel-shaped, or reel-shaped fragmentation element (hereinafter “cylinder”) or several coaxially located such elements, inside / of which there is a free-flowing or liquid explosive that occupies part of the internal volume of the cylinder, the fuse being located on the cylindrical side of the grenade.

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