RU172508U1 - Shotgun shell - Google Patents

Abstract

The utility model relates to the field of ammunition and can be used to equip cartridges for smooth-bore guns. The shot shell in the arranged position has a cylindrical shape, each shot pellet has the shape of a circle sector, the pellets are stacked in such a way that their side flat surfaces are in contact with each other , their radial surfaces form the cylindrical surface of the projectile, and the upper and lower surfaces of the grains of adjacent rows are in contact with each other in the arranged position of the projectile. The result of the utility model is to increase the lethal force of a shot projectile. 3 s.p. f-ly, 5 ill.

Description

The utility model relates to the field of ammunition and can be used to equip cartridges for smooth-bore shotguns.

A well-known hunting cartridge with steel shot for smoothbore weapons, containing a sleeve, an igniter capsule, a powder charge, a shot shell placed in a wad container, and a metal tray in the form of a cup inserted inside a polyethylene tube secured by the cup when forming the rim and the capsule socket, moreover, the wad-container is made of polymer material and consists of a container, a shock absorber and a seal, a container for placing a steel shot shell is made in the form of a glass with a cylindrical bunk a stony surface having transverse corrugations.

When fired, when the capsule igniter is triggered, the powder charge ignites, the powder gases formed as a result of its combustion create pressure on the bottom of the obturating part of the wad-container. The pressure of the powder gases through the bottom of the shutter is transmitted to the shock absorber, and at a certain pressure the shock absorber is completely compressed. Compression of the shock absorber leads to an increase in the volume of the powder chamber and, as a result, to smoothing out the peak pressure of the powder gases, as a result of which the shot is more comfortable. After the shock absorber is compressed, the pressure of the powder gases increases, the wad-container with a steel shot shell starts accelerated movement and opens the cartridge roll-in. With accelerated movement of the wad-container, the shot is compacted, it sags to the bottom of the container, and the greatest radial loads are on the walls of the bottom of the container. To maintain the integrity of the walls of the wad container from being squeezed by shot, the outer surface of the container has transverse radial corrugations and the increased wall thickness to the base is proportional to the increase in the pressure of the shot on the inner bottom surface of the container. At the exit of the wad-container from the barrel, the oncoming air flow unfolds its petals in the opposite direction from the direction of movement of the wad-container, the petals in this position play the role of a brake and a stabilizer. The corrugations on the petals of the container increase the elasticity and improve the obturation, and the notch grooves ensure their easy and uniform opening when exiting the barrel, which ultimately ensures a quick separation of the container from the shot shell without shifting the latter from the flight path (RF patent No. 2283468, class F42B 7 / 08, 2006)

As a result of the analysis of the implementation of the known cartridge, it should be noted that its design provides a fairly high accuracy of the shot when it hits the target. In addition, the implementation of the cartridge allows you to increase the volume in the sleeve for the shot shell from the classic 19 cm ³ to 22 cm ³ , which increases the lethal force of the shot shell. However, the traditional arrangement of the spherical shot in rows in the wad of the container does not provide a dense packing of the projectile, leaving a lot of empty space, which does not allow to increase the lethal force of the shot projectile to a large extent in comparison with classical shot cartridges.

A known shot for a shotgun cartridge, consisting of individual spherical pellets, in each of the pellets there is a through hole passing through its center, into which a connecting element is made, for example, from a kapron fishing line, the ends of which are fastened together and the pellets are strung on the connecting an element with a distance between them equal to the diameter of the pellet, while the number of pellets strung on the connecting element is one row of shot charge placed in the cartridge case of the shotgun.

After firing a shot, the shotguns leave the barrel of the gun under the pressure of the oncoming air flow, but this expansion limits the connecting element, as a result, each layer of shots in flight forms a stable compact group in the form of a ring. When hit by a target, the impact force (lethal force) of such a group is the sum of the kinetic energy of all the pellets interconnected, that is, it will significantly exceed the impact force of one individual pellet that hits the target (RF patent No. 2181874, class F02B 7 / 04, 2001) - the closest analogue.

As a result of the analysis of the implementation of the known shot projectile, it should be noted that it is characterized by increased lethal force, when such a projectile hits the target, the simultaneous impact of a compact group of pellets causes a shock state. However, the traditionally used spherical shape of the pellets does not allow them to be densely packed in a sleeve, leaving a lot of empty space, which reduces the total mass of the projectile, and, therefore, does not sufficiently increase its lethal force.

The technical result of the utility model consists in the beneficial use of the entire space inside the shell for placing a shell in it, which leads to an increase in the lethal force of the shot shell, which is provided by increasing the weight of the shell without increasing the volume of the shell filled by it due to the shape of the shot's shell and its packing in the shell.

The specified technical result is achieved by the fact that in a shot shell containing pellets arranged in a shell in several rows, it is new that the shot shell in a arranged position has a cylindrical shape, each shot pellet has the shape of a circle sector, the pellets are stacked in a row in such a way that their lateral flat surfaces are in contact with each other, their radial surfaces form a cylindrical surface of the projectile, and the upper and lower surfaces of the grains of adjacent rows are in contact annom projectile position, the position in the composed projectile can be placed in the wrapper, and grains of each of its row and adjacent rows may be bonded to each other, with their connector.

The essence of the claimed utility model is illustrated by graphic materials on which

 in FIG. 1 - shot shell weighing 104 g, axonometric projection;

 in FIG. 2 - shot pellet weighing 6.5 g, axonometric projection;

 in FIG. 3 - cartridge equipped with a shot shell;

 in FIG. 4 is a section HH of FIG. 3;

 in FIG. 5 is a section G-G of FIG. 3 (close-packed shot, quantity 16 pieces, projectile weight 104 g.

The shot shell 1 in the position composed of grains 2 is (Fig. 1) a cylindrical body whose diameter corresponds to the inner diameter of the cartridge sleeve so that when the cartridge is equipped, it fits tightly in the sleeve cavity, practically without a gap. The length of the cylinder 1 is standard for the charge volume of the cartridge case value.

Each pellet 2 of the projectile 1 (see Fig. 2) has the shape of a circle sector, with flat side surfaces “a” and “b”, radius surface “c”, upper flat surface “d” and lower flat surface “d”. The height of the pellet is indicated by the symbol "h".

When arranging each row of a shot projectile, the pellets 2 are stacked in such a way that their flat side surfaces “a” and “b” are in contact with each other, and the radius surfaces “c” form a cylindrical surface.

The number of grains 2 in a row may be different. So in FIG. Figure 1 shows four pellets stacked in a row, which, of course, does not mean that their number cannot be different. The size of the grains used to form the shot can vary. Most effectively, this form of pellet can be used to pack coarse shot, in particular buckshot.

A shot shell consists of several rows. When the projectile is arranged, the upper flat surfaces “g” and the lower flat surfaces “d” of the grains of adjacent rows are in contact with each other. The height (length) of the shot projectile depends on the number of stacked rows and the height “h” of the pellets.

In the formation of a shot projectile, grains in each of its rows can be bonded to each other on their flat surfaces "a" and "b" by means of a fusible adhesive applied to them. Similarly, grains of adjacent rows can be bonded by means of an adhesive applied to the flat surfaces “g” and “e”. This allows you to maintain the shape of the assembled shot shell for a long time, which greatly simplifies the process of equipping the cartridge.

To solve this problem, the assembled shot shell can be placed in a wrapper (not shown) instead of using an adhesive.

It is easy to notice that the proposed layout of the shot projectile provides a snug fit between the grains to each other, almost completely eliminating the voids between them. This allows you to significantly increase the mass of the shell due to the full use of the volume of the sleeve, and, therefore, its lethal force.

Studies have shown that when the cartridge is equipped with standard spherical buckshot with a diameter of 7 mm, 20 buckshot grapes are used, and the projectile mass is 40.8 g.

When the cartridge is equipped with buckshot with a diameter of 8 mm, 12 buckshot grapes are used, and the projectile mass is 36.5 g.

When the cartridge is equipped with buckshot with a diameter of 9 mm, 10 buckshot grapes are used, and the projectile mass is 43.3 g.

To equip the cartridge with the shot described in this utility model, we used a shot representing a sector of a circle with a radius of 9 mm, having an angular size of 90 ° and a thickness of 9 mm, 4 pellets were stacked in a row, and the number of rows was 4. Thus, when forming 16 shots were put into the same volume of the shell, and their total mass was 104 g.

It is easy to notice that the equipment of a cartridge with a projectile using such grains allows to increase the projectile mass by more than two times as compared to using standard buckshot, which significantly increases its lethal force. So, for example, if a manpower is hit by such a projectile from the action of the shot, even an armored vest will not protect, the enemy will die only due to shell shock caused by the impulse transmitted when a shot projectile hits.

To fire a shot with a shot shell 1 equip the sleeve 3 with the capsule 4 in its bottom. A powder charge 5 is placed in the sleeve, on top of which the wad 6 is placed on the sleeve, a shot shell 1 is placed on the wad, closing it from above with the wad 7, and the sleeve is rolled up, getting an equipped cartridge.

When fired, the capsule 4 initiates the ignition of the powder charge 5, as a result of which the shot projectile acquires the necessary kinetic energy and a given direction, hitting the target. If the shot shell was placed in a wrapper, then it is separated from the shell when it leaves the barrel. If the shot fraction was connected by means of an adhesive, it melts under the influence of the temperature of the powder gases and loses its adhesive properties.

When hit by a target, due to the greater mass of the projectile, its lethal force increases. In addition, with such a mass of shells, a larger number of buckshots are used, each of which has a bullet mass and can itself hit a separate target, which means that it becomes possible to hit a group target with one shot.

This shot pellet, in addition to the advantages listed above, is technologically advanced in production - individual pellets can be stamped, and the layout of the projectile can be done on automated equipment, which is very important for mass production of shells. Shotgun equipment can also be easily automated.

Claims (4)

1. A shot shell containing pellets arranged in a shell in several rows, characterized in that the shot shell in a arranged position has a cylindrical shape, each shot pellet has the shape of a circle sector, the pellets are stacked in a row so that their side flat surfaces are in contact with the other, their radial surfaces form the cylindrical surface of the projectile, and the upper and lower surfaces of the grains of adjacent rows are in contact with each other in the arranged position of the projectile. 2. The shot shell according to claim 1, characterized in that in the arranged position it is placed in a wrapper. 3. Shot shell according to claim 1, characterized in that the grains of each row are fastened together with the possibility of their connector. 4. The shot shell according to claim 1, characterized in that the grains of adjacent rows are fastened together with the possibility of their connector.

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