KR102041829B1 - Safety nozzle structure and rocket using the safety nozzle structure and grenade using the safety nozzle structure and multi-purpose shell using the safety nozzle structure - Google Patents

Abstract

The present invention relates to a safety nozzle structure for divided ignition, a rocket bomb using the same, a grenade using the same, and a multi-purpose bomb using the same, the structure comprising: a plurality of explosion signal delivering passage units provided to deliver an explosion signal by ignition of an ignition gunpowder unit to a plurality of compartments in which gunpowder or a blasting agent is located; and a safety nozzle member located in each of the explosion signal delivering passage units, and blocking the explosion signal delivering passage units when the gunpowder or the blasting agent in each compartment is exploded. Therefore, in a bomb in which a plurality of compartments are divided, and gunpowder or a blasting agent of different types is located at each compartment, an explosive energy generated in each compartment is prevented from being delivered to other compartments, thereby preventing unisonous explosions and preventing an accident caused by an unintended explosion. In addition, safety during use and reliability in operation of the gunpowder or the blasting agent located at each compartment are guaranteed. Furthermore, each portion of gunpowder or each blasting agent are made to display a function suited to a purpose, such that an effect desired to be acquired by the gunpowder or the blasting agent of each compartment can be precisely acquired.

Description

SAFETY NOZZLE STRUCTURE AND ROCKET USING THE SAFETY NOZZLE STRUCTURE AND GRENADE USING THE SAFETY NOZZLE STRUCTURE AND MULTI-PURPOSE SHELL USING THE SAFETY NOZZLE STRUCTURE}

The present invention relates to a safety nozzle structure for splitting detonation, rockets using the same, grenades using the same, and multi-purpose coals using the same. More specifically, the detonation detonation is performed so that the detonation energy generated in the compartments separated in the body is not transferred to another compartment. The present invention relates to a safety nozzle structure, a rocket bomb using the same, a grenade using the same, and a multipurpose coal using the same.

Multipurpose coal, which can be used for various purposes in the battlefield, has various shapes and structures according to various uses.

Mainly used as a detonator, the electric detonator tube, and the detonation signal is transmitted to the electric detonator tube is a separate detonation in the compartment separated by a relatively thick structure.

However, certain gunpowder and chemicals have a problem in that a synchro explosion occurs in response to a flame delivered through a small pipeline connecting the electric detonator.

In addition, in the case of multi-purpose coals in which one compartment separates internal compartments, and each compartment is filled with different gunpowder or chemicals, the other gunpowder or other chemicals located in each compartment does not perform according to the intended purpose due to a synchronized explosion. There was a problem that the user does not get the desired effect.

Registered Korean Patent No. 1485111 'Manufacturing Method of Tan Body with Integrated Separation Wall' (registered on Jan. 15, 2015)

An object of the present invention is to divide a plurality of compartments, and in each of the different types of gunpowder or chemicals in the bullet is located in the compartment for preventing the explosion explosion by preventing the explosion energy generated in each compartment to be transferred to the other compartment for The present invention provides a safety nozzle structure, a rocket coal using the same, a grenade using the same, and a multi-purpose coal using the same.

In addition, another object of the present invention is to ensure that the explosive independence of different types of gunpowder or chemicals located in each compartment to ensure that each gunpowder or each chemical product to perform the performance according to the purpose, and to obtain by the gunpowder or chemicals of each compartment The present invention provides a safety nozzle structure for a segmentation detonation capable of accurately obtaining an effect, a rocket coal using the same, a grenade using the same, and a multipurpose coal using the same.

In order to achieve the above object of the present invention, an embodiment of the safety nozzle structure for the detonation of the explosion according to the present invention is for delivering an explosion signal by the detonation of the explosives to a plurality of compartments where the gunpowder or chemicals are located A plurality of explosion signal transmission passage portion, respectively located in the explosion signal transmission passage portion and characterized in that it comprises a safety nozzle member for blocking the explosion signal transmission passage portion when explosives of the gunpowder or chemicals in each compartment.

An embodiment of the safety nozzle structure for the segmentation detonation according to the present invention may further include an explosion signal transmission member for transmitting the explosion signal of the detonation gunpowder to the gunpowder or chemicals in each compartment to operate the gunpowder or chemicals.

An embodiment of the safety nozzle structure for the segmentation detonation according to the present invention further comprises a main passage portion connected to the detonation explosive portion and a plurality of explosion signal transmission passage portion, a plurality of the explosion signal transmission passage portion is the main Branches in the passages may be connected to each compartment.

An embodiment of the safety nozzle structure for the segmentation detonation according to the present invention may further include a nozzle body portion in which a plurality of the explosion signal transmission passage portion and the main passage portion is located.

In the present invention, the cone-shaped nozzle insertion portion is gradually located at the tip end of the explosion signal transmission passage portion toward the tip side, and the safety nozzle member may be formed in a cone shape corresponding to the cone shape of the tip insert side. have.

In the present invention, at the rear end of the safety nozzle member, a pressure increasing groove portion receiving the explosion pressure in the compartment may be located.

In the present invention, the explosion signal transmitting member is a first linear powder connected to the explosive powder, the first ignition powder is located in the center of the end of the first linear powder and the branch of the explosion signal transmission passage, It may include a second linear gunpowder connected to the first ignition gun and connected to the gunpowder or chemicals in each compartment through the explosion signal transmission passage.

In the present invention, the explosion signal transmission member may further include a second ignition agent located at the outlet side of the explosion signal transmission path part and connected to the second linear gunpowder and explode the gunpowder or the chemical in the compartment.

In the present invention, the outer circumference of the safety nozzle member may be positioned so that the nozzle support legs for supporting the position of the safety nozzle member in the explosion signal transmission passage portion spaced apart in the circumferential direction.

In the present invention, the inner side surface of the explosion signal transmission passage portion may be positioned to protrude a first leg stopper portion for supporting the front end portion of the nozzle support leg portion, and a second leg stopper portion for supporting the rear end side of the nozzle support leg portion. Can be.

In the present invention, the nozzle support leg portion may be a notched groove portion to be broken by the explosion pressure of the compartment.

In the present invention, the notch groove may be located at a boundary between the nozzle support leg and an outer surface of the safety nozzle member.

In the present invention, the second leg stopper portion has a wedge shape in which the inclined surface is located toward the rear end side of the explosion signal transmission passage portion may be elastically supported by a spring.

In order to achieve the above object of the present invention, an embodiment of the rocket bomb using the safety nozzle structure for the atomization according to the present invention is a rocket bullet body in which a plurality of compartments filled with gunpowder are located therein, for the rocket bullet A solid propulsion engine located at the rear end side of the carcass, a fuse for igniting the solid propulsion engine, an explosive charge unit for applying an explosion signal for exploding a gunpowder located in the compartment, and an explosion signal of the explosive charge unit in each compartment It includes an embodiment of the safety nozzle structure according to the present invention includes a plurality of explosion signal transmission path for delivering to each other and the explosion signal transmission path is blocked in each explosion of the explosives in each compartment.

One embodiment of the grenade using the safety nozzle structure for the segmentation detonation according to the present invention in order to achieve the object of the present invention is a grenade for the grenades in which a plurality of compartments filled with gunpowder is located therein, in the compartment Detonation gunpowder for applying an explosion signal to explode the gunpowder, a grenade fuse for hitting the detonation gun to apply an explosion signal, a plurality of explosion signals for delivering the explosion signal of the explosion gun to the gunpowder in each compartment One example of the safety nozzle structure according to the present invention includes a delivery passage portion and each explosion signal transmission passage is blocked when the explosives in each compartment explode.

In order to achieve the above object of the present invention, an embodiment of the multipurpose coal using the safety nozzle structure for the segmentation detonation according to the present invention is a multipurpose application in which a plurality of compartments filled with different explosives or chemicals are located therein. And explosive explosives for applying explosive signals for exploding explosives to explode bombs, explosives or chemicals located in the compartments, and a plurality of explosive signal transmission passages for delivering explosive signals to the explosives in each compartment; Or one example of the safety nozzle structure according to the invention in which the explosion signal transmission passage is blocked when the explosion of the chemical products.

In the present invention, a plurality of compartments are divided and each compartment has a different kind of gunpowder or a chemical product, so that the detonation energy generated in each compartment is prevented from being transferred to another compartment to prevent synchronized explosions, thereby preventing accidental explosions. It is effective in preventing accidents and ensuring operational safety and operational reliability of the gunpowder or chemicals located in each compartment.

In addition, the present invention ensures that the explosive independence of the different types of gunpowder or chemicals located in each compartment to ensure that each gunpowder or each chemical product to perform the performance according to the purpose, to accurately obtain the effect to be obtained by the gunpowder or chemicals of each compartment There is an effect that can be obtained.

1 is a schematic diagram illustrating one embodiment of a safety nozzle structure for a segmentation detonation in accordance with the present invention;
Figure 2 is a schematic diagram showing the closed state of each compartment after detonation in one embodiment of the safety nozzle structure for the detonation in accordance with the present invention.
3 and 4 are cross-sectional views showing an embodiment of the safety nozzle member in the safety nozzle structure for the segmentation detonation according to the present invention.
5 is a schematic diagram illustrating one embodiment of a rocket launch using a safety nozzle structure for a segmentation detonation in accordance with the present invention.
6 is a schematic diagram illustrating one embodiment of a grenade using a safety nozzle structure for a segmentation detonation in accordance with the present invention.
7 is a schematic diagram illustrating one embodiment of a multipurpose coal using a safety nozzle structure for a segmentation detonation according to the present invention.

The present invention is explained in more detail.

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention. Prior to the detailed description of the invention, the terms or words used in the specification and claims described below should not be construed as limiting in their usual or dictionary meanings. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a schematic diagram showing one embodiment of a safety nozzle structure for a segmentation detonation according to the invention, and FIG. 2 is a post-detonation angle compartment 1 in one embodiment of a safety nozzle structure for a segmentation detonation according to the invention It is a schematic diagram which shows this sealed state.

1 and 2, an embodiment of the safety nozzle structure for dividing detonation according to the present invention includes an explosive signal due to the detonation of the detonation explosive part 100. It includes a plurality of explosion signal transmission passage portion 200 for transmitting to a plurality of compartments 1 to be.

In the explosion signal transmission path part 200, a safety nozzle member 300 which blocks the explosion signal transmission path when the explosives 2 or the chemicals 3 are exploded in each compartment 1 is positioned.

In addition, one embodiment of the safety nozzle structure for the segmentation detonation according to the present invention is to deliver the explosion signal of the explosive gunpowder 100 to the gunpowder (2) or chemicals (3) in each compartment (1) gunpowder (2) Or it further comprises an explosion signal transmission member 400 for operating the chemicals (3).

Explosive signal transmission member 400 is an example that delivers the explosion signal to the gunpowder (2) or the chemicals (3) in the compartment (1) without bursting with the linear connection gunpowder, the linear connection gunpowder is a known linear connection gunpowder It will be noted that the more detailed description that can be carried out in various modifications to omit.

The safety nozzle member 300 is positioned in the state in which the explosion signal transmission path 200 is opened so that the explosion signal transmission member 400 can pass through the explosion signal transmission path 200 and the explosion in the compartment 1. It is moved to the tip end side of the explosion signal transmission passage 200 by the pressure to prevent the explosion signal transmission passage 200 so that the gunpowder 2 or the chemicals 3 can be independently detonated in each compartment 1. .

In more detail, an embodiment of the safety nozzle structure for dividing detonation may further include a main passage part 500 connected to the detonation explosive part 100 and to which the plurality of explosion signal transmission passage parts 200 are connected.

A plurality of explosion signal transmission passage portion 200 is branched from the main passage portion 500 has a form connected to each compartment (1).

In addition, an embodiment of the safety nozzle structure for the segmentation detonation according to the present invention may further include a nozzle body portion 600 in which a plurality of explosion signal transmission passage portion 200 and the main passage portion 500 is located. The nozzle body 600 is an example of being integrally formed with the body.

In addition, the nozzle body 600 may be manufactured separately from the body and a plurality of compartments 1 in which the gunpowder 2 or the chemicals 3 are positioned may be located.

It should be noted that the plurality of compartments 1 may be located in the body body separately from the nozzle body 600, or may be located in the nozzle body 600.

The front end of each explosion signal transmission passage 200 is connected to the main passage 500, and the rear end of each explosion signal transmission passage 200 is connected to the compartment (1).

The safety nozzle member 300 is located at the distal end side of the explosion signal transmission path part 200 and opens a passage of the explosion signal transmission path part 200 so that the explosion signal transmission member 400 passes through the outer circumference. Is located.

In addition, the safety nozzle member 300 receives the explosion signal from the detonation gunpowder unit 100 and the explosives 2 or the chemicals 3 in the compartment 1 explode, and the explosion signal transmission path by the explosion pressure in the compartment 1. It is moved to the tip side of the unit 200 to block the explosion signal transmission passage 200 to block the explosion energy generated in each compartment (1) to be transmitted to the other compartment (1) to prevent the synchronization explosion.

The cone-shaped nozzle insert 200a is gradually located at the tip end of the explosion signal transmission path 200 and gradually decreases in diameter toward the tip end side.

In addition, the safety nozzle member 300 is formed in a cone shape that gradually decreases in diameter toward the tip end side and is inserted into the nozzle insert 200a to block the explosion signal transmission passage 200.

The safety nozzle member 300 is formed in a cone shape corresponding to the cone shape of the nozzle insert portion 200a by the tip end side and is expelled by the pressure in the compartment 1 in a state where the nozzle insert portion 200a is spaced apart from the nozzle insert portion 200a. Each compartment (1) is blocked by the explosion signal transmission passage part 200 by being inserted into the nozzle insertion part 200a while moving toward the distal end side of the explosion signal transmission path part 200 so that the outer circumference is in close contact with the inner circumference of the nozzle insertion part 200a. Preventing explosion explosion by blocking the detonation energy generated in the inside to be transferred to the other compartment (1).

At the rear end of the safety nozzle member 300, the pressure increasing groove 300a which receives the explosion pressure in the compartment 1 is located.

The pressure increasing groove 300a is located at the rear side in the moving direction of the safety nozzle member 300 and is formed in a hemispherical shape to receive the explosion pressure in the compartment 1 so that the safety nozzle member 300 moves faster and faster, thereby exploding the signal. It is possible to more reliably block the delivery passage portion 200.

The explosion signal transmitting member 400 is positioned at an end side of the first linear powder 410 and the first linear powder 410 connected to the explosion powder 100, and the plurality of explosion signal transmitting paths 200 diverge. Is connected to the first ignition 420, the first ignition 420 and the explosive signal transmission passage 200 is connected to the gunpowder (2) or the chemicals (3) in each compartment (1) It may include a second linear powder 430.

In addition, the explosion signal transmission member 400 is located at the rear end side of the explosion signal transmission path 200, that is, the exit side of the explosion signal transmission path 200 is connected to the second linear powder 430 and the compartment ( 1) It may further include a second ignition 440 to explode the gunpowder (2) or the chemical (3).

The explosion signal transmitting member 400 transmits the explosion signal generated by the explosion powder 100 to the first powder 420 through the first linear powder 410 and the first powder 420 is ignited. The explosive signal is transmitted to the second ignition powder through the second linear powder 430 located in the explosion signal transmission path 200, and the powder (2) or the chemicals in each compartment (1) through the ignition of the second ignition powder. (3) will explode.

When the explosives (2) or chemicals (3) in each compartment (1) is exploded, the safety nozzle member (300) is moved to the distal end side of the explosion signal transmission passage part 200 by the explosion pressure of each compartment (1) The signal transmission path 200 is blocked.

On the other hand, Figures 3 and 4 is a cross-sectional view showing an embodiment of the safety nozzle member in the safety nozzle structure for the segmentation in accordance with the present invention, referring to Figures 3 and 4 the outer periphery of the safety nozzle member 300 The nozzle support leg 310 supporting the position of the safety nozzle member 300 in the explosion signal transmission path 200 protrudes in the circumferential direction.

The safety nozzle member 300 is positioned in the center of the explosion signal transmission passage part 200 as a plurality of nozzle support legs 310 protruding from the outer circumferential surface, and the explosion signal transmission member 400 passes through the outer circumference. It forms a passageway and is located in the state in which the explosion signal transmission passage part 200 is opened.

In addition, the inner side of the explosion signal transmission passage part 200 hangs the first leg stopper 210 supporting the tip end side of the nozzle support leg 310 and the rear end side of the nozzle support leg 310. The supporting second leg stopper part 220 may be positioned to protrude.

The first leg stopper part 210 and the second leg stopper part 220 respectively support the front end side and the rear end side of the nozzle support leg 310 so as to provide a safety nozzle member within the explosion signal transmission passage 200. Fix the position of 300).

In addition, the notch groove 311 is positioned in the nozzle support leg 310 to be broken by the explosion pressure of the compartment 1.

The notch groove 311 is located on the surface of the nozzle support leg 310 facing the tip side of the explosion signal transmission passage 200 so that the nozzle support leg 310 is smoothly caused by the explosion pressure of the compartment 1. Allow it to be cut and separated.

The notch groove 311 is located at the boundary between the nozzle support leg 310 and the outer surface of the safety nozzle member 300 so that the outer nozzle support leg 310 of the complete nozzle member is cut and the safety nozzle member 300 is cut off. To be separated.

The safety nozzle member 300 is pushed by the explosion pressure of each compartment 1 and the nozzle support leg 310 is cut and separated to move to the tip of the explosion signal transmission passage 200 to explode the signal transmission passage 200. ) Will be blocked.

At this time, the nozzle support leg 310 is separated at the boundary of the outer surface of the safety nozzle member 300 to minimize the portion remaining on the outer surface of the safety nozzle member 300.

This is secured by the nozzle support leg 310 protruding around the outer side of the safety nozzle member 300 when the safety nozzle member 300 is inserted into the nozzle insert 200a to block the explosion signal transmission passage 200. The outer surface of the nozzle member 300 is prevented from coming into close contact with the inner circumferential surface of the nozzle insert 200a, and the outer surface of the safety nozzle member 300 is brought into close contact with the inner circumferential surface of the nozzle insert 200a. This is to ensure that the delivery passage portion 200 is sealed.

As an example, the second leg stopper part 220 has an inclined surface having a wedge shape located toward the rear end side of the explosion signal transmission path part 200 and is elastically supported by the spring 221.

Accordingly, the safety nozzle member 300 moves from the rear end side of the explosion signal transmission path part 200 to the tip end side of the explosion signal transmission path part 200 while being inserted into the explosion signal transmission path part 200. The nozzle support leg 310 may be positioned between the first leg stopper 210 and the second leg stopper 220 by passing through the stopper 220, and the explosion signal transmission path 200 may be It is possible to effectively limit the movement of the safety nozzle member 300 to the rear end side.

On the other hand, Figure 5 is a schematic diagram showing an embodiment of a rocket bomb using a safety nozzle structure for a segmentation detonation according to the present invention, referring to Figure 5 is a work of a rocket bullet using a safety nozzle structure for a segmentation detonation in accordance with the present invention The embodiment is a solid propulsion engine 30, a solid propulsion engine, which is located on the rear end side of the rocket carbon body 20, the rocket carbon body 20, in which a plurality of compartments 1 filled with gunpowder are located therein. The explosion ignition unit ignition unit 30, the explosive powder unit 100 for applying an explosion signal for exploding the gunpowder located in the compartment 1, and the explosion signal of the explosive powder unit 100 is transferred to the gunpowder in each compartment 1 In one example, it includes a plurality of explosion signal transmission passage portion 200 for the purpose and includes a safety nozzle structure (10) that each explosion signal transmission passage portion 200 is blocked when explosives in each compartment (1).

The safety nozzle structure 10 is respectively located in the explosion signal transmission path part 200 and the safety nozzle member which blocks the explosion signal transmission path part 200 at the time of explosion of the gunpowder 2 or the chemical product 3 in each compartment 1. 300.

The safety nozzle structure 10 including the explosion signal transmission path 200 and the safety nozzle member 300 may be implemented in duplicate with the embodiment of the safety nozzle structure for the segmentation detonation according to the present invention. Note that the description is omitted.

Explosives located in each compartment 1 are exploded by receiving the explosion signal generated from the explosive charge unit 100 to the explosion signal transmitting member 400, and at this time, the explosion signal transmission passage connected to each compartment 1 The 200 is blocked by the safety nozzle member 300 to enable independent explosion for each compartment 1 and to prevent synchronized explosion.

Figure 6 is a schematic diagram showing an embodiment of a grenade using a safety nozzle structure for a segmentation detonation according to the present invention, with reference to Figure 6 an embodiment of a grenade using a safety nozzle structure for a segmentation detonation in accordance with the present invention Detonation gunpowder unit 100 for applying the explosion signal for exploding the gunpowder for the grenades 40, the explosive gun located in the compartment 1 is a plurality of compartments (1) filled with gunpowder therein, detonation gunpowder A plurality of explosion signal transmission passages 200 for delivering the explosion signal from the grenade fuse 50 and the explosive gun 100 to apply the explosion signal to the gunpowder in each compartment (1). ), And includes a safety nozzle structure 10 in which each explosion signal transmission passage 200 is blocked when explosives are exploded in each compartment 1.

The safety nozzle structure 10 is respectively located in the explosion signal transmission path part 200 and the safety nozzle member which blocks the explosion signal transmission path part 200 at the time of explosion of the gunpowder 2 or the chemical product 3 in each compartment 1. 300.

The safety nozzle structure 10 including the explosion signal transmission path 200 and the safety nozzle member 300 may be implemented in duplicate with the embodiment of the safety nozzle structure for the segmentation detonation according to the present invention. Note that the description is omitted.

In addition, the grenade fuse 50 is a known grenade fuse that blows the explosives blown by the detonator 100, which is a primer supported by the spring 221 when the lever is separated after separating the safety clip and the safety pin. Note that more detailed description is omitted.

The safety nozzle structure 10 is branched from the main passage part 500 and the main passage part 500 in which the end side of the ball of the fuse part is inserted and the detonation explosive part 100 is located therein, and is connected to each compartment 1. It may include a nozzle body 600 in which a plurality of explosion signal transmission passage 200 is located.

Explosives located in each compartment 1 are exploded by receiving the explosion signal generated from the explosive charge unit 100 to the explosion signal transmitting member 400, and at this time, the explosion signal transmission passage connected to each compartment 1 The 200 is blocked by the safety nozzle member 300 to enable independent explosion for each compartment 1 and to prevent synchronized explosion.

Figure 7 is a schematic diagram showing an embodiment of a multi-purpose coal using a safety nozzle structure for a segmentation detonation according to the present invention, referring to Figure 7 of the multi-purpose coal using a safety nozzle structure for a segmentation detonation in accordance with the present invention An embodiment is a multi-purpose bullet body 60 having a plurality of compartments 1 filled therein with different gunpowder 2 or a work piece 3 therein, a gunpowder 2 or a chemical article located in the compartment 1 (3) the explosive explosive part 100 for applying an explosive signal for exploding, and a plurality of explosive signal transmission passage parts 200 for transmitting the explosive signal of the explosive explosive part 100 to the gunpowder in each compartment 1; It includes an example that includes a safety nozzle structure (10) that is blocked each explosion signal transmission passage 200 when the explosives (2) or chemicals (3) in each compartment (1).

The safety nozzle structure 10 is respectively located in the explosion signal transmission path part 200 and the safety nozzle member which blocks the explosion signal transmission path part 200 at the time of explosion of the gunpowder 2 or the chemical product 3 in each compartment 1. 300.

The safety nozzle structure 10 including the explosion signal transmission path 200 and the safety nozzle member 300 may be implemented in duplicate with the embodiment of the safety nozzle structure for the segmentation detonation according to the present invention. Note that the description is omitted.

The multi-purpose bullet body 60 includes at least three compartments 1 therein, and one of the compartments 1 has an explosive charge medicine 2a positioned therein, and the other one of the compartments 1 smoke bombs. As an example, (3a) is positioned, and a plurality of bullets 70 and a propellant for firing 2b for firing the plurality of bullets 70 are located in another compartment 1.

The explosives (2a), smoke bombs (3a), and propulsion for propulsion for fuel located in each compartment 1 receive an explosion signal generated from the explosive charge unit 100 to the explosion signal transmitting member 400 and explode, respectively. Debris by explosion, smoke by smoke bombs 3a, firing of a plurality of shots 70, etc. are combined.

At this time, the explosion signal transmission passage 200 connected to each compartment 1 is blocked by the safety nozzle member 300 to enable independent explosion for each compartment 1 and to prevent synchronized explosion.

According to the present invention, a plurality of compartments (1) are divided and compartments (1) having different detonation energy generated in each compartment (1) in a bullet in which different types of gunpowder (2) or chemicals (3) are located in each compartment (1). ) To prevent synchronized explosions by blocking the transmission to) to prevent accidents caused by unintentional explosions, and to ensure safety and operational reliability of the gunpowder (2) or chemicals (3) located in each compartment (1). Secure.

In addition, the present invention to ensure the explosion independence of the different types of gunpowder (2) or the chemicals (3) located in each compartment (1) so that each gunpowder or each chemicals to perform the performance according to the purpose, each compartment (1) By the gunpowder (2) or the chemicals (3) of the desired effect can be obtained accurately.

The present invention is not limited to the above-described embodiments, and various changes can be made without departing from the gist of the present invention, which is understood to be included in the configuration of the present invention.

1: compartment 2: gunpowder
2a: Claim 2b: Propellant for bullets
3: chemical product 3a: smoke bomb
10: safety nozzle structure 20: rocket bullet
30: solid propulsion engine 40: grenades for grenades
50: Fuse for grenades 60: Multi-purpose bullet
70: Chatan
100: explosion gun 200: explosion signal transmission passage
200a: nozzle insertion portion 210: first leg stopper portion
220: second leg stopper portion 221: spring
300: safety nozzle member 300a: pressure increasing groove
310: nozzle support leg portion 311: notch groove portion
400: explosion signal transmission member 410: first linear powder
420: first point powder 430: second linear powder
440: the second ignition powder 500: the main passage portion
600: nozzle body

Claims (16)

A plurality of explosion signal transmission passages for transmitting the explosion signal by the explosion of the explosion powder to a plurality of compartments in which the powder or the chemicals are located; And
And a safety nozzle member positioned in the explosion signal transmission path and blocking the explosion signal transmission path in case of explosives of the explosives or chemicals in each compartment.
The method according to claim 1,
And a explosion signal transmitting member for transmitting the explosion signal of the explosive part to the gunpowder or the chemical product in each compartment to operate the gunpowder or the chemical product.
The method according to claim 1,
And a main passage part connected to the explosive charge part and connected to a plurality of explosion signal transmission path parts.
And a plurality of explosion signal transmission passages branched from the main passage and connected to each compartment.
The method according to claim 3,
And a nozzle body portion including a plurality of the explosion signal transmission passage portion and the main passage portion.
The method according to claim 1,
The tip portion of the explosion signal transmission passage portion is located in the cone-shaped nozzle insertion portion gradually decreases in diameter toward the tip side, the safety nozzle member is characterized in that the tip side is formed in a cone shape corresponding to the cone shape of the nozzle insert portion Safety nozzle structure for split detonation.
The method according to claim 1,
The safety nozzle structure for the dividing aeration, characterized in that the pressure increasing groove portion is received at the rear end of the safety nozzle member received the explosion pressure in the compartment.
The method according to claim 2,
The explosion signal transmission member,
A first linear gunpowder connected with the explosive gun;
A first ignition gun positioned at an end side of the first linear gunpowder and positioned at a central portion where a plurality of explosion signal transmission passages branch;
And a second linear gunpowder connected to the first ignition gun and connected to the gunpowder or the chemicals in each compartment through each of the explosion signal transmission passages.
The method according to claim 7,
The explosion signal transmitting member is located at the exit side of the explosion signal transmission passage portion is connected to the second linear gunpowder and the safety nozzle structure for a segmented explosion further comprising a second ignition to explode the gunpowder or chemicals in the compartment .
The method according to claim 1,
And a nozzle support leg for supporting the position of the safety nozzle member in the explosion signal transmission path portion so as to protrude spaced apart in the circumferential direction on an outer circumference of the safety nozzle member.
The method according to claim 9,
On the inner surface of the explosion signal transmission passage portion is characterized in that the first leg stopper portion for supporting the front end side of the nozzle support leg portion, the second leg stopper portion for supporting the rear end side of the nozzle support leg portion protrudes Nozzle structure for splitting detonation.
The method according to claim 9,
The nozzle support leg portion is a safety nozzle structure for dividing aeration, characterized in that the notched groove portion is located to be broken by the explosion pressure of the compartment.
The method according to claim 11,
And the notch groove portion is positioned at a boundary between the nozzle support leg portion and an outer surface of the safety nozzle member.
The method according to claim 10,
And the second leg stopper portion has a wedge shape in which an inclined surface is located toward the rear end side of the explosion signal transmission passage portion and is elastically supported by a spring and positioned to be elastically supported.
A rocket bullet body in which a plurality of compartments filled with gunpowder are located therein;
A solid propulsion engine positioned at a rear end side of the rocket bullet body and a fuse igniting the solid propulsion engine;
An explosive charge unit configured to apply an explosion signal to explode the gunpowder positioned in the compartment; And
The safety nozzle according to any one of claims 1 to 13, which includes a plurality of explosion signal transmission passages for delivering the explosion signal of the explosives to the gunpowder in each compartment, and the explosion signal transmission passages are blocked when the explosives in each compartment are exploded. A rocket bomb using a safety nozzle structure for segmentation detonation, comprising a structure.
A grenade body in which a plurality of compartments filled with gunpowder are located therein;
An explosive charge unit configured to apply an explosion signal to explode the gunpowder positioned in the compartment;
A grenade fuse unit for hitting the explosives to apply an explosion signal; And
The safety nozzle according to any one of claims 1 to 13, which includes a plurality of explosion signal transmission passages for delivering the explosion signal of the explosives to the gunpowder in each compartment, and the explosion signal transmission passages are blocked when the explosives in each compartment are exploded. Grenade using a safety nozzle structure for segmentation detonation, characterized in that it comprises a structure.
A multipurpose bullet body having a plurality of compartments filled therein with different gunpowder or chemicals therein;
Detonation explosives for applying an explosion signal for exploding the gunpowder or chemicals located in the compartment; And
Claim 1 to claim 13 of claim 1 to 13 including a plurality of explosion signal transmission passage for transmitting the explosion signal of the explosives explosives in each compartment and exploding of the explosives or chemicals in each compartment. Multi-purpose coal using a safety nozzle structure for the segmentation detonation characterized in that it comprises a safety nozzle structure.

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