KR101517157B1 - Gas type bullet shells - Google Patents

Abstract

The present invention relates to a recyclable gas type bullet shell. The gas type bullet shell comprises: a cylindrical body including a gas storage space having a pressure hole on one side thereof and gas discharge holes on the other side thereof, a gas discharge space into which gas discharged through the gas discharge holes is introduced, and a bullet mounting space for mounting a bullet to be fired by gas introduced into the gas discharge space; a disk-shaped piston that is disposed inside the gas storage space, moves by an impact of a firing pin through the pressure hole, and discharges stored gas into the gas discharge space through the gas discharge holes; a driving unit connected to the piston to open or close the gas discharge holes by a movement of the piston; and a bullet holding unit that separates the gas discharge space from the bullet mounting space, has a disk-shaped structure for holding a bullet, and includes gas discharge holes through which gas introduced into the gas discharge space is discharged to fire a bullet.

Description

Gas type bullet shells that can be recycled

The present invention relates to a recyclable gas shell, and more particularly to a gas shell which is recyclable, suitable for use in applications other than human life, and less susceptible to safety accidents.

In general, grenades (high bombs) are a type of military weapons capable of killing human lives or using light grenade launchers to destroy light armored vehicles,

These grenades are used to kill people, and grenades are made of peonies or chemicals in bullets that are difficult to use for non-punitive purposes. Also, there is a problem that recycling of the shell can not be performed due to the control of the detonation of the grenade by the gunpowder.

On the other hand, in general, when a fire occurs, a fire extinguisher is used in which a person must directly approach a fire point and inject a fire extinguishing gas.

In addition, in the case of a fire extinguisher by a conventional water-based method, it is difficult to apply to indoors fire and it can not be used in the case of oil fire. In the conventional fire extinguisher, There is a problem that it is difficult to use it when it is difficult to access the point directly.

Solid and liquid or semi-solid warheads are being developed to solve these problems and to be used for purposes other than human life. The shell having such a warhead inserted therein is incapable of being recycled and has a structure for emitting a warhead by using a gunpowder, so that the warhead may be destroyed or exploded at the time of triggering, and a large noise may be generated.

Korean Registered Patent No. 10-1265301 (Feb.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a recyclable gas-type cartridge capable of overcoming the above-described problems.

Another object of the present invention is to provide a gas-type shell that can be recycled, has little noise at the time of triggering, and is triggered using gas.

According to an embodiment of the present invention, a gas-containing casings according to the present invention includes a gas storage space having a pressurizing portion formed at one side thereof and gas discharge holes formed at the other side thereof, A cylindrical body having a gas discharge space into which the discharged gas flows and a warhead mounting space in which a warhead to be discharged by the gas introduced into the gas discharge space is mounted; A disk-shaped piston provided in the gas storage space and moved by a blow of the ball through the pressure port to discharge the stored gas to the gas discharge space through the plurality of gas discharge holes; A driving unit coupled to the piston to open or close the gas outlet holes by movement of the piston; And a gas discharge hole for partitioning the gas discharge space and the warhead mounting space and having gas discharge holes for discharging the gas introduced into the gas discharge space.

And the other side of the gas storage space is closed by a partition wall on which the gas outlet holes are formed. The driving unit includes a disk having a predetermined diameter and a first rod projecting in the horizontal direction from the center of the disk and having a predetermined length And the first plate is inserted in a through hole formed in a central portion of the partition wall to be introduced into the gas storage space, And the end portion is coupled to the center portion of the piston.

The first rod is disposed in the gas storage space so as to be enclosed by an elastic spring so that the original plate closes the gas outlet holes before the shell is fired and is moved by the movement of the piston when the shell is fired The disk can open the gas outlet holes and after the shell is fired, the piston can be moved to the side of the pressure port by the elasticity of the elastic spring.

The body may be provided with a gas filling hole for filling gas into the gas storage space.

According to the present invention, it is possible to use a non-lethal use, less noise at the time of triggering, recycle of the shell, and fire using the gas without using gunpowder, thereby preventing a safety accident. Further, since the warhead can be variously changed as needed, there is an effect that the warhead can be used for various purposes including a fire suppression and the like.

1 is a perspective view of a gas-type casings according to an embodiment of the present invention,
FIG. 2 is a cross-sectional view taken along line AA of FIG. 1,
3 is a perspective view of the warhead rest 140 of FIG. 1,
Fig. 4 is a perspective view of the drive unit 130 of Fig. 1,
Fig. 5 is an exploded perspective view of the warhead to be mounted in the warhead attachment space of the shell of Fig. 1,
Fig. 6 (a) is a perspective view of the warhead shown in Fig. 5,
Fig. 6 (b) is a sectional view of the warhead shown in Fig. 5,
FIG. 7 is a view showing a change of the warhead at the time of launching of FIG. 6,
8 is a perspective view of a portable launch vehicle for launching a warhead;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings without intending to intend to provide a thorough understanding of the present invention to a person having ordinary skill in the art to which the present invention belongs.

FIG. 1 is a perspective view of a gas-type shell 100 according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along line A-A of FIG. Particularly, FIG. 2 (a) is a cross-sectional view showing the state of the coal-burning head, and FIG. 2 (b) is a cross- 3 is a perspective view of the warhead rest 140 of FIG. 1, and FIG. 4 is a perspective view of the drive unit 130 of FIG.

1 to 4, a gas-type shell 100 according to an embodiment of the present invention includes a body 110, a piston 160, a drive unit 130, and a warhead rest 140 .

The body 110 may have a cylindrical structure having a gas storage space 116, a gas discharge space 114, and a warhead mounting space 110 therein.

The gas storage space 116 has a pressurizing hole 118 formed at one side thereof and a gas outlet hole 115a formed at the other side thereof and includes a gas filling hole 117 for filling the gas. The gas storage space 116 is partitioned by the partition wall 115 from the gas outflow space 114 and a plurality of the gas outflow holes 115a are formed in the partition 115.

The gas outlet holes 115a may be formed in a circular shape to surround the center of the partition 115 for uniform gas outflow. A first rod 134 constituting the driving unit 130 is formed on a central portion of the partition wall 115 to have a through hole 115b for insertion into the gas storage space 116 from the gas discharge space 114 side, Respectively.

The presser foot 118 may be provided to have a larger diameter than the size of the pressure gauge of the gunpowder used in a general grenade launcher. This is to prevent a safety accident by making it impossible to use the gunpowder used in a general grenade launcher and the gas grenade using the gasket of the present invention in parallel. That is, in the case of using the portable projectile of FIG. 8, which will be described later, the conventional gunpowder grenade can not be fired due to the difference in the pressure gauge, but the gas grenade using the gasket can be fired.

The piston 160 is positioned in the gas storage space 116 to discharge gas stored in the gas discharge space 115a through the gas discharge holes 115a.

The gas storage space 116 is filled with propane gas or carbon dioxide and has a rechargeable structure, thereby contributing to the recycling of the casing.

The gas discharge space 114 is a space previously passed through the gas discharge holes 142 for discharging gas discharged through the gas discharge holes 115a, (140).

The gas discharge space 114 is provided with a disc 132 constituting the driving unit 130 so that the gas in the gas storage space 116 does not flow out into the gas discharge space 114 before the discharge of the warhead, Thereby closing the holes 115a. A sealing ring 115c such as an O-ring may be provided on the surface of the circular plate 132 facing the partition 115 or on the surface of the partition 115 facing the circular plate 132. [

The warhead mounting space 112 is a space in which the warhead 120 to be fired by the gas discharged through the gas discharge holes 142 is mounted. The warhead 120 may have a configuration in which one end thereof is in close contact with the warhead platform 140 and is stationary.

The body 110 includes a first body 110a including the pressing member 118 and a second body 110b constituting the gas storage space 116 together with the first body 110a, And a third body 110c constituting the warhead mounting space 112 and constituting the gas outflow space 114 together with the second body 110b. 2 body 110b and the second body 110b and the third body 110c may have a threaded coupling structure to facilitate separation and coupling.

The structure of the warhead 120 will be described later with reference to FIG. 5 to FIG.

The piston 160 is provided in the gas storage space 116 and moves by the impact of the ball through the pressure port 118 to discharge the gas stored in the gas storage space 116 to the gas outlet hole 115a (Not shown).

The piston 160 may have a disc shape or a cylindrical shape. The piston 160 may move in a first direction (left direction in the drawing) by pressing through the pressurizing opening 118 to open the gas storage space 116, The gas stored in the gas outlet holes 115a flows out through the gas outlet holes 115a and moves in a second direction (right direction in the figure) opposite to the first direction due to the elasticity of the spring 150 after the shell is fired, 118).

A sealing ring 118c such as an O-ring may be provided on the inner surface of the pressing hole 118 where the piston 160 contacts to prevent the gas from flowing out through the pressing hole 118 and to seal the hole.

4, the driving unit 130 is a unit that is engaged with the piston 160 to open or close the gas outlet holes 115a by movement of the piston 160, The distal end has a disc 132 and a first rod 134.

The circular plate 132 closes or opens the gas outlet holes 115a formed in the partition wall 115 and has a diameter corresponding to the position of the gas outlet holes 115a formed in the partition wall 115 And is located in the gas outlet space 114 and moves in the first direction or the second direction within the gas outlet space 114 in correspondence with the movement of the piston 160.

The disk 132 moves in the first direction in accordance with the movement of the piston 160 in the first direction to open the gas outlet holes 115a so that the gas flows out into the gas outlet space 114 And moves in the second direction in accordance with the movement of the piston 160 in the second direction to close the gas outlet holes 115a by coming into close contact with the partition 115 after the shell is fired.

The first rod 134 protrudes in the horizontal direction (second direction) from the center of the circular plate 132 and has a rod shape having a predetermined length.

The first rod 134 is inserted into the through hole 115b formed at the center of the partition wall 115 and flows into the gas storage space 116. The first rod 134 flows into the gas storage space 116, Of the piston 160 is coupled to the center of the piston 160.

The first rod 134 is coupled to the piston 160 to have a structure in which the disc 132 and the piston 160 are connected to each other. In correspondence with the movement of the piston 160, (132) can be moved.

In particular, the first rod 134 may be configured to be surrounded by the elastic spring 150 in the gas storage space 116.

Accordingly, the first rod 134 moves together with the elastic spring 150 as the piston 160 is moved toward the pressing member 118 before the shell is fired, Thereby closing the gas outlet holes 115a.

The first rod 134 compresses the elastic spring 150 by the pressure of the pusher 118 and moves the piston 160 when the shell 160 is fired. So that the circular plate 132 opens the gas outlet holes 115a as it moves in correspondence with the movement. Also, after the shell is fired, the piston 160 is moved to the side of the pressure port by the elasticity of the elastic spring 150, so that the original plate 132 closes the gas outlet holes 115a.

The driving unit 130 includes a second rod 134 protruding from the center of the circular plate 132 in a direction opposite to the first rod 134 in a first direction and having a length shorter than that of the first rod 134, 136 may be provided. In this case, the driving unit 130 has a cross-sectional structure.

The second rod 136 may have a structure in which an end portion of the second rod 136 is inserted into the through hole 144 formed in the center of the turret cradle 140 or the insertion groove. The second rod 136 has a length such that the end of the circular plate 132 does not fall out of the through hole 144 when the circular plate 132 moves in the first direction or the second direction in the gas outflow space 114. [ Lt; / RTI >

The second rod 136 is for supporting the drive unit 130 to move in a state in which the drive unit 130 is maintained in a constant path without being distorted in a vertical direction or the like when the drive unit 130 is moved in the first direction or the second direction. Since the load of the driving unit 130 is concentrated only in the through hole 115b formed in the partition wall 115 without the second rod 136, And may be provided for smooth driving of the unit 130.

The warhead rest 140 separates the gas outflow space 114 and the warhead installation space 112 and has a disc-shaped structure in which the warhead (120 in FIG. 5) Respectively.

The gas discharge holes 142 are pressed by the piston 160 in the gas storage space 116 to discharge the gas discharged through the gas discharge holes 115a through the gas discharge holes 142 So that a force can be applied to the firing of the warhead 120. The gas discharge holes 142 may be formed in a plurality of the gas discharge holes 142 so as to uniformly apply a force to the warhead 120 and not to concentrate the force on specific portions. And may be provided in a wrapping manner. The number of the gas discharge holes 142 may be greater than the number of the gas discharge holes 115a.

A through hole 144 or an insertion groove for inserting the end of the second rod 136 is formed at the center of the warrantacle rest 140 so that the end of the second rod 136 is inserted and supported.

The warhead cradle 140 can be variously changed in accordance with the structure and the shape of the warhead 120 and can have a structure that can be changed according to the type of the warhead 120.

The warhead 100 mounted on the above-described shell 100 may have various configurations, but may have a configuration as shown in FIGS. 5 to 7 as an example.

Fig. 5 is an exploded perspective view of the warhead 120 mounted in the warhead attachment space of the shell of Fig. 1, Fig. 6 (a) is a perspective view of the warhead 120 of Fig. 5, FIG. 7 is a view showing a change of the warhead 120 of FIG. 6 at the time of firing, and FIG. 8 is a perspective view of a portable projectile for firing a warhead.

5 to 8, the warhead 120 includes a liquid or semi-solid contents 122, an inner skin 124 of plastic or rubber material surrounding the contents 122, And an alabaster 128 of a paper or protein material coupled to one side of the outer shell 126. As shown in FIG.

The contents 122 may be in a liquid or semi-solid state and may include any of an extinguishing liquid for fire extinguishing, a non-salivating liquid, and a tear liquid. In addition, various liquids or semi-solid materials can be included depending on the application, such as liquids or adhesive liquids, which can slow the movement of animals or people.

The inner film 124 may have a thin vinyl-based material, a rubber material similar to a rubber balloon, or a plastic material. The inner film 124 may wrap the content 122 in the form of a capsule, I have. For example, when a water balloon filled with water is dropped or thrown at a certain height, it is the same principle as when water is dispersed by contact impact upon contact with a target.

The outer cover 126 protects the inner cover 124 surrounding the contents 122 and prevents the inner cover 124 from being damaged during transportation or mounting of the outer cover 100 in the warhead installing space 112. [ To prevent the contents 122 from flowing out, and the inner film 124 is wrapped with a material capable of spontaneous decomposition such as paper or protein. The outer shell 126 has a configuration to surround the outer circumferential surface and one side surface of the inner circumferential surface 124. The other side of the inner skin 124 may be wrapped by a skin cover (not shown) if necessary.

The outer shell 126 may have a hexagonal or octagonal cross-sectional structure with a hollow hexagonal or octagonal column shape. When the shell 120 is fired from the shell 110, So that it can be separated from the inner skin 124 by an air resistance.

For example, as shown in FIG. 7, when the warhead 120 is fired by a projectile (200 in FIG. 8), it is divided into a plurality of pieces from the tip of the warhead 120 by air resistance Structure.

The charcoal 128 is coupled to one side of the envelope 126 and has a paper or protein material. The alabaster 128 is a portion disposed in close contact with or adjacent to the gas discharge holes 142 of the shell 100, and directly acts on the gas.

The gas pressure is transmitted to the alabaster 128 to push the alabaster 128 to fire the warhead 120. At this time, 124 and the envelope 126 so as not to damage the endothelium 124 or the sheath 126 due to an impact.

In addition to the impact mitigation, the bull's nest 128 can also control the mass and range of the contents 122 of the warhead using the thickness. When the thickness of the contents 122 is increased, the mass 122 of the contents 122 can be made smaller, the range can be increased, and when the thickness is made thinner, the mass 122 of the contents 122 can be increased and the range can be reduced.

The shell 100 on which the shell 120 having the above-described structure is mounted can be fired using the portable projectile 200 as shown in Fig.

The portable projectile 200 may be configured such that the warhead 120 has a range of 10 to 20 meters.

The portable projectile 200 may be modified to use a conventional grenade launcher to remove the strand of the bullet from the projectile so as to maintain the impact amount of the bulletproof box 120 at a non-lethal level, but it may be separately manufactured. In addition, the portable projectile 200 can also be used to improve a viburnum projectile or the like that emits a bomb using gas. In this case, it is necessary to enlarge the muzzle so that the shell 100 on which the shell 120 is mounted can be introduced. In addition, it is possible to implement a portable launch vehicle 200 having various configurations at the level of ordinary technicians.

Hereinafter, the operation of the shell 100 in a state in which the shell 120 is installed will be described.

2 (a), gas is filled in the gas storage space 116, the piston 160 is in close contact with the side of the pressure applying hole 118, And closes the gas outlet holes 115a. In addition, the warhead 120 is mounted in the warhead installation space 112.

In this state, when the ball (or the air pressure or the hydraulic pressure) of the portable projectile 200 presses the presser foot 118 for launching, as shown in FIG. 2 (b) The piston 160 moves in the first direction while pressurizing the gas in the gas storage space 116 by the pressure through the piston 160. The piston 132 of the driving unit 130 is moved in the first direction by the movement of the piston 160 so that the gas outlet holes 115a are opened to allow the gas to flow through the gas outlet holes 115a. And then flows into the gas outlet space 114. The gas introduced into the gas outflow space 114 is discharged through the gas discharge holes 142 of the warhead support 140 to pressurize and fire the warhead 120 mounted in the warhead installation space 112. After the warhead 120 is fired, the driving unit 130 and the piston 160 are moved in the second direction by the resilience of the elastic spring 150 as the pressure through the pressing member 118 is removed do. Accordingly, the piston 160 is in close contact with the pressure port 118, and the disc 132 is restored to the state of closing the gas outlet holes 115a.

Then, the gas storage space 116 is filled with gas and the new warhead 120 is loaded through the gas filling hole 117 for recycling of the shell 100.

That is, when the shell 120 is fired, the shell 100 remains inside the portable projectile 200 or is discharged to the outside, and only the shell 120 is fired. Here, the shell 100 may be recycled by separating the portable projectile 200 from the portable projectile 200 and recharging the gas.

As described above, the shell 100 according to the embodiment of the present invention can be used for non-lethal use, can recycle the shell, and can be fired using gas without using gunpowder, have. Further, since the warhead can be variously changed as needed, there is an effect that the warhead can be used for various purposes including a fire suppression and the like.

The foregoing description of the embodiments is merely illustrative of the present invention with reference to the drawings for a more thorough understanding of the present invention, and thus should not be construed as limiting the present invention. It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the basic principles of the present invention.

110: body 120: warhead
130: drive unit 140: warhead cradle
150: elastic spring 160: piston

Claims (4)

delete For gas shell casings:
A gas discharge space in which a gas flowed out through the gas discharge holes is introduced and a gas discharge space for discharging the gas discharged from the gas discharge space into the gas discharge space, A cylindrical body having a warhead mounting space for mounting the warhead;
A disk-shaped piston provided in the gas storage space and moved by a blow of the ball through the pressure port to discharge the stored gas to the gas discharge space through the plurality of gas discharge holes;
A driving unit coupled to the piston to open or close the gas outlet holes by movement of the piston;
And a gas discharge hole for partitioning the gas discharge space and the warhead mounting space and having a disc-shaped structure in which the warhead is stationary, and gas discharge holes for discharging gas introduced into the gas discharge space to discharge the warhead, ,
The other side of the gas storage space is closed by a partition formed with the gas discharge holes,
The driving unit may include a circular plate having a predetermined diameter and a first rod projecting in the horizontal direction from the center of the circular plate and having a predetermined length,
And the first rod is inserted into a through hole formed in a central portion of the partition wall to be introduced into the gas storage space, Is coupled to a central portion of the piston. The method of claim 2,
The first rod is disposed in the gas storage space so as to be enclosed by an elastic spring so that the original plate closes the gas outlet holes before the shell is fired and is moved by the movement of the piston when the shell is fired Wherein the disc causes the gas outlet holes to be opened, and after the discharge of the warhead, the piston is moved to the side of the pressing port by the elasticity of the elastic spring. The method of claim 3,
And a gas filling hole for filling the gas in the gas storage space is provided in the body.

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