KR102063848B1 - Cartridge case with double cartridge chamber and ammunition comprising the same - Google Patents

Abstract

A shell and ammunition are provided that allow the pressure generated by the propellant to act uniformly on the carcass, prevent leaks before the propellant is combusted, enable complete combustion of the propellant, and expect a uniform firing rate. A casing according to the present invention is connected to a primer assembly and has a first shell having a propellant vaporized by ignition by the primer, and a second shell which is detachably coupled to the first shell and accommodates the shell. And a closure coupled to the skin and the second shell to close the propellant and to burn upon vaporization of the propellant to provide a path of movement of the propellant. Accordingly, it is possible to facilitate the complete combustion of the propellant through the casing of the double chamber structure and the closing portion that controls the movement of the propellant, and it is possible to convert the energy burned by the propellant into the firing speed. And through the formation of a constant pressure can be expected a body with a uniform firing speed.

Description

Shell with double chamber structure and ammunition comprising same {CARTRIDGE CASE WITH DOUBLE CARTRIDGE CHAMBER AND AMMUNITION COMPRISING THE SAME}

The present invention relates to a casing having a double chamber structure and to an ammunition comprising the same, wherein the pressure generated in the propellant acts uniformly on the body, and is easier to manufacture and assemble than the single chamber structure, and also leaks before the propellant is burned. The present invention relates to a casing and an ammunition which can prevent this from happening and enable complete combustion of the propellant to improve uniformity of firing speed.

Ammunition is a generic term for explosive materials designed to damage people, equipment, or structures, and is a device loaded with explosives, explosives, flares, ignition compounds, or NBC materials, depending on the purpose. to be. Ammunition can also be used for training, ceremonial, and non-shooting purposes. However, it is mainly used for military purposes. Ammunition is the most commonly known ammunition and is mainly used for guns and guns. The device that fires bullets can be divided into guns and rockets. The rocket is equipped with an acceleration propulsion device, that is, a gas injector, in the bullet itself, indicating that the injection force is used to fly most or a portion of the range by itself. In general, gun fire means that bullets are accelerated in gun barrels and barrels by the force of gunpowder, springs, air, electricity, etc., and the ballistics are to fly free ballistics by inertia after the bullet leaves the barrel. Bullets are widely known as bullets and are used by mounting on guns.

Guns are guns with a caliber of about 10mm and are designed to be carried by individuals. Depending on the function, it is divided into pistol, rifle and machine gun. Pistols are short and small guns that can be handled with one hand. Rifles are longer and larger guns than handguns and are used on the shoulders. The machine gun is a gun in which bullets are fired continuously, and has a longer effective range, superior power and continuous shooting ability than the rifle. When the gun is fired, it is divided into gunpowder, spring, air compression and pump. Gunpowder means that the gunpowder is fired by the force of the gas generated by the explosion. On the other hand, the spring type uses the force of spring elasticity, and the air type uses the force by releasing compressed air momentarily. Pumping produces compressed air with pumping and fires ammunition with that energy. Finally, the classification based on the type of bullet can be divided into short coal, shot coal, gas coal and dread coal. Single bullet fires one bullet at a time. Shotguns fire two or more bullets at a time. A gas bomb is a tear gas or choking agent that is fired by the power of a gunpowder, and a dread bomb is a gunpowder gas without a warhead and only a sound.

The firing process consists of loading, closing, triggering and firing, extracting and discharging. If we look at the important triggering and firing processes here, the firing of ammunition from the gun causes the primer to ignite when the ball hits the primer at the bottom of the shell. A detonator is a metal tube for ignition used to ignite gunpowder such as shells or bullets and is ignited by an impact. It is usually made of copper or its alloys and contains a shock-sensitive initiator inside. The detonator is the part that determines the performance of the ammunition and, depending on the position of the detonator, distinguishes between Rimfire and Centerfire. Rimfires act as detonators across the bottom of the casing and ignite when the ball strikes the bottom edge of the casing. Centerfire has a primer at the center of the bottom of the casing, which fires when the ball hits the center. Rimfire is used when the diameter of the casing is so thin that the entire base of the casing must be used as a primer. However, because Centerfire is more stable and reusable than Rimfire, Centerfire is widely used. The flame generated by the rim fire type or the center fire type primer is ignited by the impact and propagates through the flame hole into the casing. A casing is a metal cylindrical container that occupies most of the shell shape. The casing contains a propellant, and gas is produced as the propellant is burned by the flame generated by the primer. At this time, the body is fired by the pressure of the gas generated from the propellant. Common ammunition has a single chamber structure with one chamber space. Also, in general, in case of a casing having a single chamber structure, ignition of the propellant sometimes occurs unevenly. The flames do not ignite the propellant evenly, leaving unburned propellant. Therefore, the chamber internal pressure buildup that occurs at this time is not constant every time it is fired. The carcass is fired by the generated pressure. If this pressure is uneven, it becomes difficult for the carcass to hit the target accurately.

In addition, if the propellant in the casing leaks before it is burned by the flame of the primer, the propellant remaining without burning occurs, causing a problem that becomes slower than the expected firing speed.

An object according to an embodiment is to improve the dispersion degree by stabilizing the posture and ensuring uniformity of the initial firing rate, to provide an ammunition in which the propellant combustion pressure acting on the bottom of the body uniformly.

It also provides an ammunition that prevents leakage before the propellant is burned, leading to complete combustion of the propellant, thereby improving uniformity in firing speed.

In addition, in applying a double chamber structure consisting of a dual provides a structure separated into two structures to facilitate the manufacturing and assembly process.

Problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to an embodiment for achieving the above object, the casing of the present invention is connected to the primer assembly and having a propellant vaporized by ignition by the primer assembly, so as to be separable from the first shell case. And a sealing portion coupled to the second shell portion containing the body and the second shell portion to close the propellant and combust during vaporization of the propellant to provide a movement path of the propellant. The first casing portion includes a first casing connecting portion into which the second casing portion is inserted and connected, and a lower portion of the high pressure chamber in which a propellant is accommodated, and the second casing portion includes a second casing connecting portion connected to the first casing connecting portion and the The upper part of the high pressure chamber connected to the lower part of the high pressure chamber, the low pressure chamber in which pressure is formed by the gas generated by ignition of the propellant, and the upper part of the high pressure chamber and the low pressure chamber are separated. Is provided with a partition wall and a plurality of propellant flame holes are formed through the circumferential direction in the circumferential direction around the lower center and the center of the second shell portion of the partition wall to communicate the upper pressure chamber and the low pressure chamber through which gas is propagated. The sealing portion is provided at an upper portion of the propellant flame hole, the uppermost portion of the first casing connecting portion is formed higher than the upper portion of the high pressure chamber, and the lower portion of the high pressure chamber is recessed in an inner bottom.

According to one side, the first casing portion may include a primer conjugate part coupled to the primer conjugate and a primer flame hole through which the flame generated from the primer conjugate propagates.

delete

delete

delete

Ammunition according to another aspect of the present invention is a propellant which is dispersible, a second shell containing the body, detachably coupled to the second shell, connected to the primer and vaporized by ignition by the primer Coupled to the first shell portion and the second shell portion having a closed propellant and combusted during vaporization of the propellant to include a seal for providing a movement path of the propellant; A first casing connecting portion to which a second casing portion is inserted and connected, and a lower portion of the high pressure chamber containing a propellant, wherein the second casing portion is inserted into and connected to the first casing connecting portion and An upper part of the high pressure chamber connected to the lower part, a low pressure chamber in which pressure is formed by a gas generated by ignition of the propellant, and a part separating the upper pressure chamber from the upper pressure chamber. And a propellant flame hole through which a plurality of walls are formed at regular intervals in the circumferential direction around the lower center and the center of the second shell part of the separation wall so as to communicate the upper portion of the high pressure chamber with the low pressure chamber. The sealing part is provided above the propellant flame hole, the uppermost part of the first casing connection part is formed higher than the upper part of the high pressure chamber, and the lower part of the high pressure chamber is recessed in an inner bottom thereof.
According to one side, the first shell portion may include a coupling part to which the primer can be coupled and a primer flame hole through which the flame generated from the primer is propagated.

delete

delete

 According to another aspect of the present invention, a method of manufacturing a casing is connected to a primer assembly to form a first casing having a propellant, the second casing being detachably coupled to the first casing and receiving a second body. Forming a casing, wherein the second casing is coupled to the second casing and includes a seal to control movement of the propellant; wherein the first casing and the second casing are doubled And forming a bond and filling the propellant of the combined casing, wherein the first casing includes a first casing connecting portion to which the second casing is inserted and connected, and a lower portion of the high pressure chamber in which the propellant is accommodated. The second casing portion is provided by a second casing connecting portion connected to the first casing connecting portion, an upper portion of the high pressure chamber connected to a lower portion of the high pressure chamber, and a gas generated by ignition of the propellant. A plurality of low pressure chambers having a force formed therein, a partition wall separating the upper part of the high pressure chamber and the low pressure chamber, and a plurality of penetrating parts are formed at regular intervals in the circumferential direction around the bottom center and the center of the second shell part of the partition wall, And a propellant flame hole in which gas propagates in communication with the low pressure chamber, wherein the closed portion is provided above the propellant flame hole, and the uppermost portion of the first casing connection portion is formed higher than the upper portion of the high pressure chamber. The lower portion is recessed in the inner bottom.

As described above, according to the embodiments of the present invention, it is possible to facilitate the complete combustion of the propellant through the casing of the double chamber structure and the sealing portion that controls the movement of the propellant.

In addition, it is possible to convert the energy of burning all the propellant to the launch rate. And through the formation of a constant pressure can be expected a body with a uniform firing speed.

By applying a double chamber structure composed of a double, it is possible to facilitate the manufacturing and assembly process by separating the casings into the first and second casings.

1 is a cross-sectional view of ammunition according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the second shell part of FIG. 1. FIG.
3 is a plan view of the second shell part of FIG.
4 is a flow chart of a gas generated in the first shell part of FIG.

Hereinafter, the embodiments will be described in detail with reference to the accompanying drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In addition, in describing the embodiment, when it is determined that the detailed description of the related well-known configuration or function interferes with the understanding of the embodiment, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. When a component is described as being "connected" or "coupled" to another component, that component may be directly connected or connected to that other component, but another component is "connected" between each component. It should be understood that it may be "coupled".

Components included in one embodiment and components including common functions will be described using the same names in other embodiments. Unless stated to the contrary, the description in any one embodiment may be applied to other embodiments, and detailed descriptions thereof will be omitted in the overlapping range.

Referring to the drawings, the ammunition 10 according to the present invention includes a shell 100 and a shell 200.

1 is a cross-sectional view of ammunition according to an embodiment of the present invention.

Referring to FIG. 1, the casing 100 includes a first casing 110 and a second casing 120, wherein the first casing 110 and the second casing 120 are coupled and separated. The structure is possible, and the second shell part has a structure for accommodating the body 200.

The casing 100 is a metal cylindrical container that occupies most of the shell shape. It is mainly made of brass, and in other words, it is also called Yakhyup. When the gun is fired, the bullet moves toward the target, but the shell is separated from the bullet and falls out of the gun. In the general case, the casing structure has a single chamber structure having a single space. However, in the present invention, the casing structure includes a double chamber structure including a first casing part 110 and a second casing part 120.

Here, the first shell part 110 is a primer flame hole 112 in which the flame generated from the primer coupling member 111 and the primer is moved, and a lower portion of the high pressure chamber having a propellant generating gas by the generated flame ( 113) and a first casing connecting portion 114 having a structure in which the first casing portion 110 and the second casing portion 120 are connected to each other.

First, the primer coupling part 111 is located under the primer flame hole 112 as a part to which the primer, which is a metal pipe for ignition, can be coupled. A detonator is a metal tube for ignition used to ignite gunpowder, such as shells and bullets, and is ignited by impact. It is usually made of copper or its alloys or aluminum and contains an initiator inside. The material of the primer depends on which initiator is used. Detonators are shock-sensitive materials such as lead nitride, cerebral palsy, and DDNP. The initiator is produced by placing it in a small metal tube. When a shock is applied to the primer, the detonator of the primer creates a flame by the impact. The structure of the primer is largely divided into Rimfire and Centerfire, depending on where the primer is located. Rimfire (Rimfire) is the base of the casing to serve as a primer, when the ball hits the edge of the casing will generate a flame. Centerfire is a detonator attached to the center of the bottom of the casing, and when the ball hits this area, a flame is generated. In modern times, Centerfire is used a lot for stability and the possibility of recycling.

The primer flame hole 112 connects the primer coupling part 111 and the lower chamber 113 to allow the flame generated from the primer to move to the lower chamber 113.

Next, the high pressure chamber lower portion 113 is connected to the high pressure chamber upper portion 121 and forms a detachable structure or a structure in which gas generated from the propellant burned when it is connected does not leak. When the flame generated in the primer assembly moves to the primer flame hole 112, the propellant in the combination of the lower chamber 113 and the upper chamber 121 is exploded. This propellant is composed of compounds or mixtures that cause instantaneous combustion or decomposition reactions by light stimuli such as heat, electricity, impact, and the like, which produce gases with heat and pressure to destroy and propel.

The first casing connecting portion 114 forms a structure in which the first casing portion 110 and the second casing portion 120 are engaged, and the first casing connecting portion 114 has an outer side than the second casing connecting portion 122. Configure. For example, the first casing connecting portion 114 and the second casing connecting portion 122 may be fixed with a screw, but the present invention is not limited thereto and may be variously changed according to the shape of the connecting portion.

FIG. 2 is a cross-sectional view of the second shell part of FIG. 1. FIG.

Next, referring to FIG. 2, the high pressure chamber top 121 in which a propellant is provided and the gas generated therein is filled, the second casing connection portion 122 connected to the first casing part 110, and the upper portion of the high pressure chamber 121. ) Propellant flame located at the top of the separation wall 123 separating the low pressure chamber 126, the propellant flame hole 124 connecting the upper part of the high pressure chamber 121 and the low pressure chamber 126, and the propellant flame hole 124. It is composed of a closed portion 125 for closing the ball and a low pressure chamber 126 filled with the gas generated from the propellant.

First, the upper portion of the high pressure chamber 121 is provided with a propellant, and the propellant is a part in which gas is generated by explosion by the flame. The high pressure chamber upper part 121 is connected to the high pressure chamber lower part 113 of the first casing part 110 and is connected in a detachable structure. When the high pressure chamber upper part 121 and the high pressure chamber lower part 113 are connected, the gas generated from the burned propellant does not leak.

Next, the second casing connecting portion 122 constitutes an outer side of the upper portion of the high pressure chamber 121, and has a structure in which the second casing connecting portion 122 is engaged with the first casing connecting portion 114 of FIG. 1. The second casing connecting portion 122 constitutes an inner side than the first casing connecting portion 114 and has a smaller diameter. For example, the first casing connecting portion 114 and the second casing connecting portion 122 may be fixed with a screw, but the present invention is not limited thereto and may be variously changed according to the shape of the connecting portion.

In addition, the dividing wall 123 is a structure that separates the high pressure chamber upper part 121 and the low pressure chamber 126.

The propellant flame hole 124 penetrates the dividing wall 123 to connect the high pressure chamber upper part 121 and the low pressure chamber 126. The gas generated from the propellant is the low pressure chamber in the upper pressure chamber upper part 121. It is a passage to 126.

The low pressure chamber 126 is connected to the high pressure chamber upper part 121 through the propellant flame hole 124 and has a structure capable of accommodating a circular body 200. As gas generated by the propellant in the low pressure chamber 200 pushes up the body 200, the body 200 is finally fired toward the target.

3 is a plan view of the second shell part of FIG.

Next, referring to FIG. 3, the propellant flame holes 124 are formed in plural numbers at regular intervals in the circumferential direction about the center and the center of the separation wall 123. In the drawings, six flame holes are arranged based on the center and the center, but the present invention is not limited thereto, and the shape, arrangement, and number of the flame holes may be changed in various ways.

In addition, the sealing unit 125 is located at the top of the propellant flame hole 124, and controls the gas passing through the propellant flame hole 124. The sealing part 125 may be formed in various ways depending on the shape, arrangement, and structure of the propellant flame hole 124 in a structure capable of sealing the propellant flame hole 124. The sealing part 125 seals the propellant flame hole 124 until the combustion of the propellant, so that the propellant does not leak from the combination of the high pressure chamber upper part 121 and the high pressure chamber lower part 113 of FIG. By preventing the leakage of the propellant, the effect that is expected to produce ammunition in the production is shown.

 The seal 125 is composed of a material that can be combusted so that it is combusted together when the propellant is combusted.

4 is a flow chart of a gas generated in the first shell part of FIG.

Next, referring to FIG. 4, the gas delivered from the high pressure chamber upper part 121 to the low pressure chamber 126 through the propellant flame hole 124 pushes the body 200 accommodated in the low pressure chamber 126. Form.

The operation according to the present invention will be described based on the structure described above.

1 is a cross-sectional view of ammunition according to an embodiment of the present invention.

Referring to Figure 1, when the ball hits the primer located on the primer assembly coupled to the primer coupling part 111 on the bottom of the casing, the initiator in the primer is shocked to generate a flame.

Then, the generated flame is delivered to the lower chamber 113 through the primer flame hole 112. The transmitted flame combusts the propellant provided in the combination of the high pressure chamber lower 113 and the high pressure chamber upper 121. At this time, gas is generated as the propellant is burned. At this time, the flame stays in the high pressure chamber by the sealing part 125 which has closed the propellant flame hole 124 to enable complete combustion of the propellant. The complete combustion of the propellant can be expected to improve the uniformity of the firing speed of the body.

Thereafter, the sealing part 125 made of a combustible material is burned by the flame. As the seal 125 is burned, the propellant flame hole 124 is opened. Gas generated from the propellant combusted through the open propellant flame hole 124 moves to the low pressure chamber 126 through the propellant flame hole 124. The gas moved to the low pressure chamber 124 pushes the carbon body 200 accommodated in the low pressure chamber 124. At this time, the gas generated from the propellant is temporarily moved through the open propellant flame hole 124 to push the body at a uniform pressure. As the gas moved to the low pressure chamber 126 pushes the body 200 accommodated in the second shell part 120, the body is fired to the outside.

10: ammo, 100: casing
110: the first shell portion, 111: the primer binding part
112: primer flame, 113: lower chamber
114: first shell casing, 120: second shell
121: upper portion of the high pressure chamber, 122: second casing connecting portion
123: dividing wall, 124 propellant flame
125: airtight portion, 126: low pressure chamber
200: body

Claims (9)

A first casing portion connected to the primer conjugate and having a propellant vaporized by ignition by the primer assembly;
A second shell portion coupled to the first shell portion and detachably coupled to the shell; And
A closure part coupled to the second shell part to close the propellant and combusted upon vaporization of the propellant to provide a movement path of the propellant;
Including,
The first casing portion includes a first casing connecting portion to which the second casing portion is inserted and connected, and a lower portion of the high pressure chamber in which a propellant is accommodated.
The second casing portion may include a second casing connecting portion connected to the first casing connecting portion, an upper portion of the high pressure chamber connected to a lower portion of the high pressure chamber, a low pressure chamber in which pressure is formed by a gas generated by ignition of the propellant; A plurality of separation walls separating the upper part of the high pressure chamber from the low pressure chamber and a plurality of penetrating through the circumferential direction are formed in the circumferential direction around the center and the lower end of the second shell part of the separation wall so as to communicate gas between the upper part of the high pressure chamber and the low pressure chamber. With propellant flame propagation,
The closure is provided on top of the propellant flame hole,
The uppermost part of the first casing connecting portion is formed higher than the upper portion of the high pressure chamber,
The lower case of the high pressure chamber is characterized in that the recess is formed in the inner bottom surface.
The method of claim 1,
The first shell part
A primer conjugate coupling part coupled to the primer conjugate; And
Primer flame hole propagates the flame generated in the primer conjugate;
Casings comprising a.
delete delete delete Scatterable carbons;
A second shell part accommodating the bullet body;
A first shell portion having a propellant coupled to the second shell portion so as to be separable, connected to a primer and having a propellant vaporized by ignition by the primer; And
A closure part coupled to the second shell part to close the propellant and combusted upon vaporization of the propellant to provide a movement path of the propellant;
Including,
The first casing portion includes a first casing connecting portion to which the second casing portion is inserted and connected, and a lower portion of the high pressure chamber in which a propellant is accommodated.
The second casing portion may include a second casing connecting portion inserted into and connected to the first casing connecting portion, an upper portion of the high pressure chamber connected to a lower portion of the high pressure chamber, and a low pressure chamber in which pressure is formed by a gas generated by ignition of the propellant; And a plurality of separation walls through which the upper part of the high pressure chamber and the lower pressure chamber are separated, and a plurality of penetrating parts are formed at regular intervals in the circumferential direction around the center and the bottom of the second shell part of the separation wall so as to communicate the upper part of the high pressure chamber with the low pressure chamber. Propellant flame hole through which gas is propagated,
The closure is provided on top of the propellant flame hole,
The uppermost part of the first casing connecting portion is formed higher than the upper portion of the high pressure chamber,
The lower portion of the high pressure chamber is ammunition in which a recess is formed in the inner bottom.
The method of claim 6,
The first shell part
A coupling part to which the primer conjugate may be coupled; And
Primer flame hole propagates the flame generated in the primer conjugate;
Ammunition comprising a.
delete Forming a first casing with propellant connected to the primer assembly;
Forming a second shell portion detachably coupled to the first shell portion and accommodating the carbon shell;
Forming a second shell portion including a sealing portion coupled to the second shell portion to control movement of the propellant;
Forming a double bond between the first shell portion and the second shell portion; And
Filling the propellant of the combined casing;
The first casing portion includes a first casing connecting portion to which the second casing portion is inserted and connected, and a lower portion of the high pressure chamber in which a propellant is accommodated.
The second casing portion may include a second casing connecting portion connected to the first casing connecting portion, an upper portion of the high pressure chamber connected to a lower portion of the high pressure chamber, a low pressure chamber in which pressure is formed by a gas generated by ignition of the propellant; A plurality of separation walls separating the upper part of the high pressure chamber from the low pressure chamber and a plurality of penetrating through the circumferential direction are formed in the circumferential direction around the center and the lower end of the second shell part of the separation wall so as to communicate gas between the upper part of the high pressure chamber and the low pressure chamber. With propellant flame propagation,
The closure is provided on top of the propellant flame hole,
The uppermost part of the first casing connecting portion is formed higher than the upper portion of the high pressure chamber,
The lower portion of the high-pressure chamber is a method of manufacturing a casing in which a recess is formed in the inner bottom.

Images