KR101829206B1 - Thrust generating device - Google Patents

Abstract

The present invention relates to a thrust generating device, and more particularly, to a thrust generating device which includes a housing 10 having upper and lower openings and a housing space 11 formed therein, a housing 10 inserted into the housing space 11 through a lower portion of the housing 10, An ignition vessel 30 disposed in the accommodation space 11 and shielding the lower portion of the housing 10 and filled with a gun powder 31 therein; And is disposed between the ignition vessel 30 and the discharge bundle 20 and moves toward the upper portion of the housing 10 when the explosive 31 is burned to discharge the discharge bundle 20, And a piston 40 that shields the upper portion of the flame to minimize the leakage of flames and gas generated during the combustion of the powder.
The present invention has the advantage of minimizing the occurrence of flames, gas leakage, and noise during operation and enabling efficient combustion of the explosive.

Description

{THRUST GENERATING DEVICE}

The present invention relates to a thrust generating device, and more particularly, to a thrust generating device that discharges a specific object (e.g.

The thrust generator is a device that is necessary for the weapon system that emits the warhead, checks the exact enemy position while flying over a certain distance, and destroys through the upper attack.

The thrust generators developed for the release of warheads must reliably fly the warhead at a certain distance in order to allow the sensors in the warhead to detect the position of the enemy tank and fire the penetrators.

The thrust generator discharges the warhead by using the energy that is generated when the discharge bundle is discharged due to the pressure generated when the powder is burned.

However, since the conventional thrust generator is an open type in which the energy generated by the gunpowder combustion is discharged during the discharge of the bullet, the gunpowder generating the thrust can not be efficiently utilized because the force is not concentrated, And there is a high risk of being exposed to the enemy.

An object of the present invention is to provide a method and apparatus for discharging a specific object (e.g., a warhead) at a desired distance and height by using a high pressure generated by a gunpowder combustion, and minimizing the occurrence of flames, gas leakage, noise, And to provide a thrust generating device.

According to an aspect of the present invention, there is provided a portable terminal comprising: a housing having an upper portion and a lower portion opened and a receiving space formed therein; A discharge bundle inserted into the accommodating space through the lower portion of the housing and positioned to shield the upper portion of the housing so as not to be discharged by the engaging end provided on the upper portion of the housing before the powder burning; An ignition vessel disposed in the accommodation space and shielding the lower portion of the housing and filled with gunpowder; Wherein the ignition device is disposed between the ignition container and the discharge bundle and moves toward the upper portion of the housing when the powder is burned to discharge the discharge bundle and shield the upper portion of the housing, To prevent the piston from leaking; And a shock absorbing ring fixed to the housing to relieve a collision between the piston and the housing when the piston moves in the housing direction, wherein the ignition vessel is provided with a housing lower portion for depressurizing a high- And a plurality of oblique holes are formed.

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A wedge-shaped groove is formed between the shock-absorbing ring and the inner wall of the housing, and a wedge-shaped protrusion is formed at an edge of the corresponding piston to fit in the wedge-shaped groove.

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In the present invention, a piston is moved by a gun powder combustion to generate a thrust to discharge a discharge bundle to discharge a specific object (warhead) that is in contact with the discharge bundle, and a flame and gas generated during the explosive discharge Structure.

Accordingly, since the gunpowder can be completely burned, the gunpowder can exhibit the same performance with a small amount of gunpowder compared with the conventional gunpowder.

In addition, the present invention has the effect of preventing the housing explosion due to the increased combustion pressure after discharge of the discharge bundle, because the hole is formed in the ignition vessel so as to reduce the high pressure generated during combustion of the powder explosive.

1 is a sectional view showing a thrust generator according to a preferred embodiment of the present invention.
FIG. 2 to FIG. 4 illustrate operation of the thrust generator according to the embodiment of the present invention. FIG.
5 is a photograph showing the states before (a) and after (b) operation of the thrust generator according to the embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The thrust generating device of the present invention is designed with a thrust generating structure and a closed structure for an optimal thrust generating environment.

1, the thruster generating device includes a housing 10, an emitter bundle 20, an ignition vessel 30, and a piston 40. [

The housing 10 is formed in a substantially cylindrical shape and has upper and lower openings and a receiving space 11 formed therein. The discharge chamber 20, the ignition vessel 30, and the piston 40 are inserted and fixed in the accommodation space 11.

The discharge bundle 20 is formed in a cylindrical shape and is inserted into the accommodation space 11 through the lower portion of the housing 10 and is positioned to shield the upper portion of the housing 10. The discharge bundle 20 is discharged to the outside of the housing 10 by the movement of the piston 40 in the upward direction of the housing. Here, the upper portion of the housing 10 refers to the direction in which the discharge bundle 20 is discharged, and the lower portion refers to the opposite direction.

A specific object (for example, warhead 70) in contact with the discharge bundle 20 due to the energy released by the discharge bundle 20 is pushed out. The discharge bundle 20 is formed with a contact groove 21 which is open toward the upper side of the housing 10 and in which the warhead can contact.

And a locking end 23 is provided on the upper side of the housing 10. The engaging step 23 fixes the edge of the discharge bundle 20 and restrains the discharge bundle 20 from being discharged from the housing 10 before the gunpowder 31 is burned. The discharge bundle 20 can be discharged to the outside of the housing 10 while breaking the portion of the holding end 23 by energy at the time of discharge.

The ignition vessel 30 is disposed in the housing space 11 of the housing 10 to shield the lower portion of the housing 10. The ignition vessel (30) is filled with gun powder (31).

When ignited, the gunpowder 31 moves the piston 40 toward the upper portion of the housing 10 while generating gas of high temperature and high pressure. The gunpowder 31 may be a high performance gunpowder. Here, the thrust can be controlled by adjusting the amount of the explosive to adjust the desired production pressure to produce the necessary pressure.

It is preferable that the ignition vessel 30 is opened or thin as a cover at a portion in contact with the piston 40 so that a high-temperature, high-pressure gas is generated in the direction of the piston 40 when the explosive is ignited.

The piston (40) is disposed between the ignition vessel (30) and the discharge bundle (20). The piston 40 moves upward in the housing 10 to discharge the discharge bundle 20 and shield the upper portion of the housing 10 so that the flames and gas generated during the combustion of the explosive 31 leak to the outside .

The piston 40 is configured to allow the combustion of the gunpowder 31 to be carried out in an enclosed space between the piston 40 and the ignition vessel 30 so that the gunpowder 31 can be completely burned and a smaller amount of gunpowder 31) to achieve the same performance.

The piston 40 has a flat surface in contact with the ignition vessel 30 and is provided with a seating surface 41 recessed to stably support the discharge bundle 20 on a surface in contact with the discharge bundle 20, Is further protruded in a wedge shape.

A shock absorbing ring 50 is provided for shock absorption and external hermetic sealing when the piston 40 and the housing 10 collide with each other.

The shock absorbing ring 50 is fixed at the edge of the upper space 11 of the housing 10 to relieve the collision between the piston 40 and the housing 10 when the piston 40 moves toward the housing 10. The shock absorbing ring 50 may be made of a rubber material having a shock absorbing function, a soft material, or the like.

A wedge-shaped groove 51 is formed between the shock absorbing ring 50 and the inner wall of the housing 10 and a wedge-shaped protrusion (not shown) which is fitted in the wedge-shaped groove 51 at the edge of the corresponding piston 40 43 are formed.

The wedge-shaped groove 51 and the wedge-shaped projection 43 improve the adhesion performance of the shock absorbing ring 50 and the piston 40 upon impact. That is, the wedge-shaped groove 51 and the wedge-shaped protrusion 43 improve the adhesion performance between the shock absorbing ring 50 and the piston 40, so that flames and gas generated during the combustion of the gunpowder 31 are supplied to the housing 10 So as not to leak to the outside.

A through hole (33) is formed in the ignition vessel (30) to open in the lower direction of the housing (10). The through hole (33) is provided with an igniter (60) for igniting the gun powder (31) when current is applied. The through hole (33) is provided with an igniter (60) to be sealed from the outside.

The ignition vessel (30) is provided with an oblique hole (35) which opens in the lower direction of the housing (10). The holes 35 are formed in a plurality of holes spaced apart from each other by a predetermined distance around the through-holes 33, and have a diagonal hole with a narrow gap between the holes 35 at the outlet portion to reduce the pressure of the high- .

Since the flame and gas generated during the combustion of the explosive 31 do not leak to the outside through the upper portion of the housing 10, the housing 10 can explode as the combustion pressure increases.

Accordingly, it is necessary to reduce the pressure of the high-pressure gas by arranging a plurality of small holes 35 through which the combustion pressure can be discharged in the downward direction of the housing 10. Accordingly, it is possible to prevent the explosion of the housing 10 due to the high-pressure gas, and the flame and sound are not generated during operation of the thrust generator, thereby preventing exposure after operation from the enemy. As shown in VIEW A of FIG. 2, in the present embodiment, the hole 35 is provided with six small holes to depressurize the high-pressure gas generated in the combustion of the powder gun.

The operation of the present invention will be described below.

The present invention is a thrust generating device for refueling a warhead, which is in contact with a discharge bundle, with a certain distance in a reproducible manner by using the energy that is generated when a discharge bundle is discharged due to a pressure generated in the combustion of a powder explosive.

The operation of the thrust generator will be described with reference to FIGS. 2 to 4. FIG.

2, when current is applied to the igniter 60, the igniter 60 ignites the gunpowder 31 contained in the ignition vessel 30. As shown in FIG.

As shown in Fig. 3, the ignited powder gun 31 moves the piston 40 upward while generating gas of high temperature and high pressure.

At this time, as shown in FIG. 4, the discharge bundle 20 starts to move by the movement of the piston 40 and is discharged to the outside of the housing 10. That is, the piston 40 is moved to the upper portion of the housing 10 by the high-temperature and high-pressure gas to generate the thrust to discharge the discharge bundle 20 to the outside of the housing 10.

At this time, the bullet (70) which is in contact with the discharge bundle (20) is pushed out by using the released energy. The piston 40 stops moving while colliding with the housing 10 during the discharge of the discharge bundle 20 and the impact is reduced by the shock absorbing ring 50 located in the housing 10 upon impact.

The shock absorbing ring 50 is closely contacted between the housing 10 and the piston 40 so as to have a sealing structure in which the powder ignition pressure is not discharged to the upper portion of the housing 10.

As a result, the flame and gas generated during the combustion of the explosive (31) do not leak to the upper side of the housing (10), so that the gunpowder can be completely burned, the flame does not leak to the outside during operation, The device is prevented from being exposed after operation.

The high temperature and high pressure gas filled between the piston 40 and the ignition vessel 30 is discharged through the plurality of oblique holes 35 formed in the ignition vessel 30 after discharge of the discharge bundle 20, The generated high pressure can be reduced and the explosion of the housing 10 due to the increase in internal combustion pressure can be prevented.

Fig. 5 is a photograph showing the state before (a) and after (b) of the operation of the thrust generator according to the embodiment of the present invention.

5, after the operation of the thrust generator (b), it is confirmed that the piston blocks the upper portion of the housing to prevent the housing explosion.

The above-described thrust generating device has a structure that minimizes the leakage of flame and combustion gas during operation. Since the gunpowder is burnt in an enclosed space between the piston 40 and the ignition container 30, the gunpowder can be completely burned, The same performance can be exhibited with a smaller amount of gunpowder than that of the method, and light and sound are not generated during operation, thereby preventing exposure after operation from the enemy.

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

10: housing 11: accommodation space
20: emitter bundle 21: contact groove
23: latching end 30: ignition container
31: Gunpowder 33: Through-hole
35: hole 40: piston
41: seat surface 43: wedge-
50: shock absorbing ring 51: wedge shaped groove
60: Igniter 70: Warhead

Claims (5)

A housing having an upper portion and a lower portion opened and having a receiving space therein;
A discharge bundle inserted into the accommodating space through the lower portion of the housing and positioned to shield the upper portion of the housing so as not to be discharged by the engaging end provided on the upper portion of the housing before the powder burning;
An ignition vessel disposed in the accommodation space and shielding the lower portion of the housing and filled with gunpowder;
Wherein the ignition device is disposed between the ignition container and the discharge bundle and moves toward the upper portion of the housing when the powder is burned to discharge the discharge bundle and shield the upper portion of the housing, To prevent the piston from leaking; And
And a shock absorbing ring fixed to the housing to relieve a collision between the piston and the housing when the piston moves toward the housing,
Wherein the ignition vessel is provided with a plurality of oblique holes which are opened toward the lower side of the housing so as to depressurize the high-pressure gas generated during combustion of the explosive powder. delete delete The method according to claim 1,
Wherein a wedge-shaped groove is formed between the shock-absorbing ring and the inner wall of the housing, and a wedge-shaped projection is formed at an edge of the corresponding piston, the wedge-shaped projection being inserted into the wedge-shaped groove. delete

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