KR102041828B1 - Projectile having high explosive and submunition - Google Patents

Abstract

The present invention relates to a projectile having a dispersed bomblet unit and a high explosive. According to the present invention, the projectile is capable of double hitting an enemy camp by debris due to the dispersed bomblet unit and debris of an air frame due to the explosion by exploding the high explosive located inside after discharging the dispersed bomblet unit to the target point. Therefore, the damage of the enemy camp can be greatly increased. According to the present invention, it is possible to maximize the efficiency of a shell by hitting different targets by sequentially performing a heterogeneous explosion.

Description

PROJECTILE HAVING HIGH EXPLOSIVE AND SUBMUNITION}

The present invention relates to a projectile having a dispersal bomb and a high explosive, and more particularly, to a double warhead structure having a dispersal bomb in the high bomb body, having a dispersal bomb and a high explosive capable of further increasing damage to the forward. The invention relates to a projectile.

Common shells are divided into high-bomb warheads and dispersed warheads.

A high-explosive warhead is a shell in which a high explosive is embedded and the body is ruptured by the explosive pressure and formed into debris to damage the enemy.

Dispersed warheads are warheads containing a large number of scattered bullets that are exploded and dropped during flight.

In addition, the scattered charcoal fuse is activated by the impact force generated when the impact on the ground, and the peony is exploded therein to cause fragments to be fired, causing great damage to people or objects.

The high-bomb warhead inflicts peripheral damage with a simple high-strength energy and debris, but has a disadvantage in that it cannot do great damage to enemy vehicles.

Dispersed Warhead is also a weapon that kills enemy tanks and nearby horses using scattered bullets. However, the discharging warhead has a disadvantage in that the bullet body loaded with the dispersal bomb after falling down by discharging the dispersal carbon falls.

As a prior patent related to the present invention, Korean Patent Registration No. 1259734 has been proposed.

Korean Patent Registration No. 1259734 'Projectile with Dispersed Coal' is a projectile containing dispersant bombs inside, and it disperses and disperses the dispersed bombs to the target point, and the bullet body is dropped because it has a structure that does not play a role. There is a disadvantage in that it can not cause more damage, but only damage caused by scattered bombs.

Korean Patent Registration No. 1259734 'Projectile with Dispersed Coal' (registered on April 24, 2013)

The object of the present invention is to disperse the flying bomb to the target point and then discharge the high explosives located inside the debris due to the scattered bombs in the enemy, the explosive detonation of the explosives due to the explosion of the explosives, It is to provide a projectile with a high explosive.

In order to achieve the object of the present invention described above, the projectile having a discharging bomb and a high explosive according to the present invention is divided into a high explosive charge filling space in which a high explosive charge is filled and a space for inserting a plurality of dispersing bombs. Firing body positioned so as to be filled, a high explosive charge portion filled in the high explosive charge filling space in the firing body, a plurality of dispersing coals inserted into the shell inserting space, a shell discharging portion which releases and disperses the dispersing carbon from the firing body, and discharging the coal; It is characterized in that it comprises a fuse unit for activating the unit, and detonated by exploding the high explosives after the operation of the magnetic release unit.

In the present invention, the firing body is a carcass inner skin where the high explosive charge filling space is located, the inside of the carcass insertion space with the rear opening is located inside the outer body is spaced apart from the inner surface of the carcass outer shell, It may be detachably coupled to the rear end side of the carcass inner skin includes a stopper for blocking the open rear portion of the shell insertion space, the fuse portion may be located at the front end of the body shell skin.

In the present invention, the launch vehicle may further include an endothelial support for supporting the position of the carcass inner skin portion so that the outer periphery of the carcass inner skin portion is spaced apart from the inner surface of the carcass outer skin portion.

In the present invention, the endothelial support portion is a first endothelial support portion connecting the carcass outer skin and the rear end portion of the carcass inner skin and the first endothelial support and the tip end portion is located spaced apart from the rear end portion of the carcass outer skin and the carcass inner skin It may include a second endothelial support connecting the side and the plurality of high explosive charge filling openings located in the circumferential direction.

In the present invention, the shell release portion may include a discharge plate member movably positioned in the insertion space of the shell and a propulsion tube member for propellant ignited by the fuse portion located therein and pushing the discharge plate member to move. .

In the present invention, the propulsion pipe member may be positioned in a state in which the fuse portion and one end portion of the propeller pipe portion which are located at the tip end side of the shell body skin are supported and the other end is supported by the discharge plate member.

In the present invention, the body inner skin portion is located in the explosion prevention portion extending from the point where the discharge plate member is located to the tip side to form a high explosive explosion-proof space that is an empty space therein, the explosion-proof portion in the shape of a cone gradually decreases in diameter Is formed and the end is fixed to surround the outer surface of the propulsion pipe member can form a high explosive explosion-proof space therein.

In the present invention, a propellant ignition detonator tube projecting is connected to an internal ignition unit and ignited by an ignition unit to ignite the propellant, and a propellant ignition detonator is formed between the fuse unit and the propellant member. A high explosive powder ignition unit may be positioned to explode and explode the high explosive powder after a predetermined time after the pipe part passes and the propellant is ignited.

In the present invention, the high-explosive powder ignition unit is fixed to the one end side is mounted to the rear of the fuse portion, the other end is connected to the propulsion pipe member, the propellant ignition detonating tube section through the first hole through the through hole and the side side An ignition block body which is opened and is located between the first detonation tube through hole connecting the first detonation tube through hole and the high explosive charge filling space, and is located in the first detonation tube through hole and is located outside the propellant ignition detonation tube part. A first ignition retardant surrounding a side, a second ignition retardant protruding from the first ignition retardant, and a second ignition retardant positioned within the second blast through hole and the second ignition retardant to detonate the high explosives It may include a detonation tube portion.

In the present invention, the second ignition retardant is filled in a portion in the second detonation tube through-hole, and the high-width detonation tube portion is positioned to fill the remaining portion of the second detonation tube through-hole and contact the high explosive charge portion. Can be.

In the present invention, the first ignition retardant may be formed to have a size covering the outer surface of the propellant ignition detonator tube part and completely blocking the first through hole.

The projectile having a dispersal charcoal and a high explosive according to the present invention is disposed after the plurality of dispersal bombs and a high explosive charge is located therein and then releases a plurality of dispersal charcoal drops after a predetermined time, and the dispersal char is discharged. After the set time, the high explosive charge is characterized in that the explosion.

According to the present invention, after discharging the dispersal bomb to the target point, the explosives located inside the explosion explode and the double explosives by the fragments of the firing body can be damaged by the debris of the dispersal bombs and the explosive explosives. There is an effect that can be greatly increased.

The present invention has the effect of maximizing the efficiency of the shell can be hit by different targets by sequentially performing a heterogeneous explosion.

1 is a cross-sectional view showing an embodiment of a projectile having a dispersal bomb and a high explosive according to the present invention.
Figure 2 is an enlarged cross-sectional view showing the main portion of an embodiment of the fuse unit in the projectile having a dispersion bomb and a high explosive according to the present invention.
Figure 3 is a cross-sectional view showing an embodiment of the dispersal charcoal in the projectile having a dispersal charcoal and a high explosive according to the present invention.
4 is a view showing an example in which a plurality of dispersed charcoal is released from a projectile having a dispersing charcoal and a high explosive according to the present invention.
Figure 5 is a flow chart illustrating an explosion process of the projectile with a dispersal bomb and a high explosive 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 cross-sectional view showing an embodiment of a projectile having a dispersal bomb and a high explosive according to the present invention, and referring to FIG. 1, a projectile having a dispersal bomb and a high explosive according to the present invention is filled with a high explosive charge therein. The space 100a and the bullet insertion space 100b include a firing bullet body 100 positioned to be separated.

The firing body 100 has an internal notch or embossing shape, and it will be noted that a more detailed description thereof is omitted as a known launching body 100 that can be fired by a gun or a launch pad and fly toward a target.

The high explosive charge filling space 100a is a space where the high explosive charge is filled, and the high explosive explosive part 200 is formed to detonate and explode the firing body 100 to form a plurality of fragments that can hit the target.

The high explosive charge unit 200 is an example of a high explosive charge such as RDX, TNT, PETN, HMX, etc., and is variously modified to a known high explosive to form a plurality of debris to be fired by exploding the firing body 100 It can be revealed.

In addition, a plurality of dispersed charcoal 600 is positioned in the bullet insertion space 100b, and the dispersed charcoal 600 is filled with high explosives inside the charcoal and collides with a target on the ground to explode to scatter a plurality of debris. It is composed.

The dispersal bomb 600 detonates the inner connector of the fuse through a vertical impact through the striker when it collides with a target on the ground or the ground to explode the internal alleged medicine, and when it falls, it expands to maintain the posture for posture maintenance and fuse loading. It is noted that the included one as an example and described in more detail below.

The plurality of dispersed charcoal 600 is discharged by the operation of the bullet discharge unit 300 after a predetermined time after the firing bullet 100 is fired from the gun.

In addition, the fuse unit 400 operates the bullet discharge unit 300 after a predetermined time after the firing body 100 is fired from the gun, and after the predetermined time after the bullet discharge unit 300 is operated, the high explosive charge unit Can detonate (200).

More specifically, the firing carcass 100 has a shell body shell 110 in which the high explosive charge filling space 100a and the shell inserting space 100b are located, and a shell inserting space 100b having a rear portion opened therein. The outer periphery is detachably coupled to the rear end side of the carcass inner skin 120 and the carcass inner skin 120 which are positioned to be spaced apart from the inner surface of the carcass outer skin 110 to stop the open rear portion of the shell insertion space 100b. The unit 130 may be included.

The body body shell 110 includes a cylindrical main body and a cone body having a cone shape that gradually decreases in diameter toward the distal end side on the distal end side of the cylindrical main body.

At the tip of the cone body, a fuse 400 for activating the bullet discharge part 300 and detonating the high explosive charge part 200 is located.

The stopper 130 is coupled to the carcass inner skin 120 so that the plurality of dispersed charcoal 600 inserted therein is separated from the open rear portion of the jatan insertion space 100b until the carbon discharging part 300 is operated. In addition, when the shell discharge unit 300 is operated, the shell body is separated from the inner shell body 120 and the rear portion of the shell insertion space 100b is opened to release the plurality of dispersed shells in the shell space 100b. To be possible.

The stopper 130 may be coupled to the inner body of the body 120 by an interference fit or may be coupled by bolt fastening, or may be coupled in a structure including a locking groove inserted into the locking jaw and the locking jaw, or a known separation. It is to be understood that various modifications can be made using possible coupling structures.

The stopper 130 is maintained in a state in which it is coupled with the carcass inner skin 120 so as to support the load of the dispersed charcoal 600 inserted into the charcoal insertion space 100b, and by the operation of the charcoal discharge part 300. It should be noted that various modifications can be made to a known coupling structure that can be separated from the inner skin 120.

In addition, the firing carcass 100 may further include an endothelial support part 140 supporting the position of the carcass inner skin 120 such that the outer periphery of the carcass inner skin 120 is spaced apart from the inner surface of the carcass outer skin 110. Can be.

The carcass inner skin 120 is formed of a cylindrical body having a smaller diameter than the carcass outer skin 110 and is spaced apart from the carcass inner skin 120 within the carcass inner skin 120 to be high explosive between the carcass outer skin 110. That is, it can be filled, that is, a space in which the high explosive charges 200 are located to be formed.

Endothelial support 140 is a first endothelial support portion 141, the first endothelial support portion 141 and the tip end side that is connected to the outer end side of the carcass outer skin 110 and the carcass inner skin 120 is located and the outer shell body The second endothelial support part 142 may be connected to the rear end of the carcass inner skin part 120 and the plurality of high explosive charge filling openings 142a may be positioned in the circumferential direction.

The second endothelial support part 142 has a plurality of high explosive charge filling openings 142a positioned in the circumferential direction and is integrally formed with the high explosive charge part 200 which is filled in the shell body shell part 110 together with one ignition. Let it explode.

The high explosive charge part 200 may be integrally located within the shell body shell 110 without being divided through the high explosive charge filling opening part 142a of the second endothelial support part 142.

 As an example, the second endothelial support 142 is located at a boundary portion between the cylindrical main body and the cone body.

The high explosive charge filling space 100a may be divided into a first charging space at the front end side and a second charging space at the rear end side on the basis of the second endothelial support part 142, and in the first charging space and the second charging space. Each high explosive charge unit 200 is filled with a high explosive charge.

The first charge space and the second charge space are connected through the high explosive charge filling opening portion 142a to form the high explosive charge portion 200 which is filled in the shell body 110 and integrally exploded together in one ignition. It will be possible.

The first endothelial support part 141 and the second endothelial support part 142 support the position of the carcass inner skin part 120 so as to space the outer periphery of the carcass inner skin part 120 and the inner surface of the carcass outer skin part 110. The high explosive charge filling space 100a may be positioned around the outer circumference of the 120, and the high explosive charge 200 may be positioned to surround the outer circumference of the carcass inner skin 120.

The high explosive chemical part 200 is positioned to surround the carcass inner skin 120 to explode to form the entire body shell 110 as a plurality of debris and to form the entire body body inner shell 120 as debris. Can be.

That is, the shell outer shell 110 and the shell inner shell 120 form a plurality of debris each to hit the enemy by the explosion of the high explosive charge unit 200, and a large amount of debris can hit a large number of enemies with shells. The power of is greatly increased.

In addition, the bullet discharge part 300 is a discharge plate member 310 which is movably located in the insert space 100b, the propellant 320a ignited by the fuse unit 400 is located inside the discharge plate member ( It includes a propulsion pipe member 320 for pushing 310.

The propulsion pipe member 320 is positioned with the fuse portion 400 located at the front end side of the shell body shell 110 and one end thereof connected to the other end thereof being supported by the discharge plate member 310.

The propulsion pipe member 320 is located in the tip end side of the shell body 110, that is, in the cone body, one end side is connected to the fuse pipe 400 and the other end side is in close contact with one surface of the discharge plate member 310 Is placed in a state.

The discharge plate member 310 has a disc shape, and its outer circumferential surface is supported on the inner circumferential surface of the shell insertion space 100b, that is, the inner surface of the carcass inner skin 120, so that the propulsion force generated by the combustion of the propellant 320a in the propulsion pipe member 320 is performed. As a result, the plurality of dispersed charcoal 600 is pushed out while moving to the rear side of the body body inner skin 120.

In the bullet insertion space 100b, a plurality of columns of columns in which a plurality of dispersed carbons 600 are arranged in a row are positioned, one side of the plurality of columns of carbon is supported by the discharge plate member 310 and the other of the plurality of carbons is plugged. Positioned in a supported state.

The plurality of columns of columns in which a plurality of pieces of carbon are arranged in a line are positioned between the discharge plate member 310 and the plug portion 130 in the portion of the carbon insertion space 100b.

In addition, the body inner skin 120 may be provided with an explosion prevention part 150 extending from the point where the discharge plate member 310 is positioned to the tip end side to form a high explosive explosion prevention space 151 therein. .

Explosion prevention unit 150 is formed in a cone shape gradually decreasing in diameter and the end is fixed to the outer surface of the propulsion pipe member 320 is an example of forming a high explosive explosion prevention space 151 therein.

The outer periphery of the inner shell body 120, that is, a space excluding the bullet insertion space 100b in the inner shell body 120 and the high explosive explosion preventing space 151 in the explosion preventing unit 150. The high explosive charge part 200 is formed between the outer circumference of the explosion prevention part 150 and the shell body shell 110.

When the propellant 320a of the propulsion pipe member 320 is burned and pushed to move the discharge plate member 310, the rear of the propulsion pipe member 320 is opened and the flame of the propellant 320a is discharged from the discharge plate member 310. Exposed between the propulsion pipe member 320 may explode by detonating the high explosive chemicals (200).

Explosion prevention unit 150 is formed to extend from the initial position of the discharge plate member 310 to the front end side and one end is fixed to the outer surface of the propulsion pipe member 320, high explosive charge filling space around the propulsion pipe member 320 A high explosive explosion prevention space 151 partitioned with 100a is formed.

Explosion prevention unit 150 forms a high explosive explosion prevention space 151, which is an empty space that is not filled with the high explosives 200 is wrapped around the rear side of the propulsion pipe member 320 of the propulsion pipe member 320 The flame caused by the combustion of the propellant 320a discharged from the rear side is blocked from the high explosive charge part 200 which is filled in the outer shell part 110, and the ignition of the high explosive charge part 200 is prevented.

Figure 2 is an enlarged cross-sectional view of the main portion showing an embodiment of the fuse unit 400 in the projectile having a dispersal bomb and a high explosive according to the present invention, referring to Figure 2 fuse unit 400 is a shell body shell 110 In the tip end side, that is, the front end of the cone body is located in the ignition unit (not shown) to ignite the propellant (320a), an impact fuse that can detonate the high explosives (200) when an impact occurs.

A propellant ignition detonator 410 for igniting the propellant 320a by being ignited by the ignition unit is connected to the rear side of the fuse unit 400 to protrude.

In addition, between the fuse 400 and the propelling pipe member 320, the propellant ignition detonator 410 is passed and after the predetermined time after the propellant 320a is ignited, the high explosive charge unit 200 is detonated A high explosive detonator 500 may be located to allow the explosion.

The high explosive detonator 500 is fixed to one end is mounted on the rear of the fuse 400, the propellant member 320 is connected to the other end and the propellant ignition detonator 410 penetrates in the longitudinal direction Ignition block body in which the first detonation tube through-hole 511 and the second detonation tube through-hole 512 are opened to the side and connect the first detonation tube through-hole 511 and the high explosive charge filling space 100a. 510, a first ignition retardant 520 and a first ignition retardant 520 positioned in the first detonation tube through-hole 511 and surrounding the outer surface of the propellant ignition detonator 410, protruding from the first ignition retardant 520. And a second explosion retardant 530 positioned in the two-aperture tube through-hole 512 and a high explosion detonator 540 for detonating from the second ignition retardant 530 to detonate the high explosive charge part 200. .

The second ignition retardant 530 is filled in a part in the second detonation tube through-hole 512, and the high-width detonation tube section 540 fills the remaining portion of the second detonation tube through-hole 512, and the high explosive charge portion ( 200).

The propellant ignition detonator tube portion 410 protrudes toward the rear of the fuse unit 400 and passes through the first detonator tube passage hole 511 so that a portion of the end side is inserted into the propellant 320a of the propellant member 320. Is located.

In addition, the first ignition retardant 520 is formed to surround the outer surface of the propellant ignition detonator tube portion 410 and is sized to block all the first detonation tube passage hole 511.

That is, the propellant 320a is primarily ignited by the propellant ignition detonator 410 by the operation of the ignition unit of the fuse unit 400, and is ignited by the ignited propellant detonation detonator 410.

In addition, the high explosive charge unit 200 is preset by delaying the explosion of the high explosive detonator tube 540 by the first ignition retardant 520 and the second ignition retardant 530 after the propellant 320a is ignited. After time, the high-explosion detonator tube 540 is secondly detonated, the detonation by the detonated high-explosion detonator tube 540 is to explode.

Figure 3 is a cross-sectional view showing an embodiment of the dispersed charcoal in the projectile having a dispersion bomb and a high explosive according to the present invention.

Referring to FIG. 3, the jet charcoal is filled with a high explosive powder 53 and a cylindrical chatan body 51 in which a conical penetrator 54 is installed inside the rear end, and a connection pipe 70 at a central portion thereof. The connector tube mounting hole is formed and is coupled to the upper end of the chatan body 51, the chatan body portion 50 and the connector 70 made of a helper 52 for sealing the upper end of the chatan body 51 Detonation tube 65 for detonating the high explosive powder 53, the slider 63 is installed to be movable horizontally on the fuse body 61 and the detonation tube 65 is assembled, and a plurality of locking projections formed on the edge Fuse base plate 62 coupled to the lower portion of the fuse body 61 through the 62 'and screwed to the fuse body 61 to limit the movement of the slider 63, but is unfolded when released to the outside of the shell A sinking screw 64 which is rotated by a ribbon 66 to allow movement of the slider 63; And a fuse assembly (60) including a stud (67) inserted into a stud insertion hole formed in the portion (52) to couple the fuse body (61) to the chattan body portion (50).

That is, when the dispersed charcoal 600 is discharged from the shot inserting space 100b of the firing body 100, the ribbon 66 is unfolded to allow the movement of the slider while the sinking screw 64 is rotated together with the ribbon and the slider is moved. When the detonation tube 65 is located in a line with the submerged screw 64 in the lower portion of the submerged screw 64 is in the loaded state.

Then, when the shell body portion 50 collides with the ground, the inertia additionally moves downward by inertia, and the sinking screw 64 moves together to detonate by hitting the detonator tube 65.

Dispersed charcoal 600, in addition to the impact that occurs when the impact of the impact when the impact of the ground when falling to the ground 64 is known to be variously deformed to be implemented by a distributed dispersed charcoal structure that hits the detonator tube 65 to detonate .

4 is a view showing an example in which a plurality of dispersed charcoal 600 is released from a projectile having a dispersion bomb and a high explosive according to the present invention, Figure 5 is a projectile having a dispersion bomb and a high explosive according to the present invention. Is a flow chart illustrating the explosion process.

1 to 5, the projectile having a dispersal bomb and a high explosive according to the present invention is operated by the ignition unit in the fuse unit 400 after a predetermined time, through the propellant ignition detonator tube unit 410 through the propellant 320a. Ignite.

The propellant 320a is ignited and burned to generate a propulsive force to push the discharge plate member 310 to separate the stopper 130 to open the rear seat insertion space 100b.

Then, the plurality of dispersed charcoal 600 positioned in the magnetic insertion space 100b is discharged to the rear side of the open magnetic insertion space 100b which is pushed by the discharge plate member 310 and falls.

The dispersal charcoal 600 is discharged from the shell inserting space 100b of the firing body 100 and the fuse loading state in which the submerged screw 64 can strike the detonator tube 65 by the rotation of the ribbon 66. If it is located in the fall, and collides with the ground or the target while falling, the sinking screw 64 hits the detonator tube 65 and detonates and destroys ground weapon devices such as horse killing and chariots.

In addition, the firing shell 100 in which the discharging charcoal 600 is discharged maintains flight toward another target and falls and collides with the target to operate the impact fuse so that the high explosive charge unit 200 is detonated to kill a man or propellant. After the propellant 320a is ignited through the ignition detonator 410, the ignition of the high detonation detonator 540 is delayed by the first ignition retardant 520 and the second ignition retardant 530. After a while, the explosion-explosive detonator 540 is detonated, and the detonation detonation detonator 200 is detonated by the detonated detonator detonator 540 to kill a horse.

According to the present invention, after discharging the discharging charcoal 600 to a target point, the explosives located inside the explosion explode and the fragments by the dispersing charcoal 600 in the enemy's enemy, the debris of the firing body 100 due to the explosive explosives. Double hits are possible, which can greatly increase enemy damage.

The present invention is capable of hitting different targets by sequentially performing a heterogeneous explosion to maximize the efficiency of the shell.

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.

100: firing body 100a: high explosive charge space
100b: jatan insertion space 110: shell body skin
120: carcass inner skin 130: stopper
140: endothelial support 141: first endothelial support
142: second endothelial support 142a: high explosive charge filling opening
150: explosion prevention unit 151: high explosive explosion prevention space
200: high explosives 300: bullet discharge part
310: discharge plate member 320: propulsion pipe member
320a: Propellant 400: new fuse
410: detonator for ignition propellant 500: detonator for high explosives
510: block body for ignition 511: first hole through hole
512: second detonation tube through hole 520: first ignition retardant
530: second ignition retardant 540: high-explosion detonator
600: dispersed coal

Claims (12)

A firing bullet body having a high explosive charge filling space therein and a shot insertion space into which a plurality of dispersed carbons can be inserted;
A high explosive charge portion filled in the high explosive charge filling space in the firing body;
A plurality of dispersed carbons inserted into the magnetic carbon insertion space, and a carbon discharge part for discharging and dispersing the dispersed carbons from a firing body; And
A fuse unit for activating the bomb release unit and detonating and exploding the high explosive charge unit after the bomb release unit is operated,
The firing body is,
An outer shell portion in which the high explosive charge filling space is located;
An inner shell portion having a rear portion opened therein and having an outer circumference spaced apart from an inner surface of the shell outer shell portion;
A stopper part detachably coupled to a rear end side of the body inner skin to block an open rear part of the shell insertion space;
And an endothelial support for supporting a position of the body inner skin part such that the outer circumference of the body body skin is positioned to be spaced apart from the inner surface of the body body skin part.
The fuse portion is located at the tip of the body shell,
The endothelial support,
A first endothelial support portion connecting the outer shell portion and the rear end portion of the shell inner skin portion; And
And a second endothelial support part positioned to be spaced apart from the first endothelial support part and the distal end part and connecting the carbon outer skin part to the rear end part of the carbon inner skin part and having a plurality of high explosive charge filling openings in the circumferential direction.
The magnetic release part is a discharge plate member movably positioned in the magnetic insertion space; And
A propellant ignited by the fuse part is located therein and includes a propulsion pipe member for pushing the discharge plate member,
The explosion inner part is located in the body inner skin extending from the point where the discharge plate member is located to the tip side to form a high explosive explosion prevention space that is empty inside,
The explosion prevention portion is formed in a cone shape gradually decreasing in diameter and the end is fixed to surround the outer surface of the propulsion pipe member to form a high explosion explosion prevention space therein,
The high explosive charge portion is filled in the entire space inside the shell body skin except the high-explosion explosion-proof space in the inner shell of the carcass and the explosion insert in the inner shell body of the shell body to surround the body of the carcass body And a portion surrounding the explosion prevention portion between the outer circumference of the explosion protection portion and the shell body skin is integrally formed through the high explosive charge filling opening and formed integrally with the projectile.
delete delete delete delete The method according to claim 1,
The propulsion pipe member is provided with a dispersal charcoal and a high explosive, characterized in that the fuse portion and the one end is connected to the distal end portion of the shell outer skin portion and the other end is located in a state supported by the discharge plate member. Projectile.
delete The method according to claim 1,
A propellant ignition detonator tube part protruding from the rear of the fuse part is connected to an ignition part inside and ignited by the ignition part to ignite the propellant.
Between the fuse portion and the propulsion pipe member is characterized in that the explosive detonator for propellant ignition detonator passes and the explosive detonator exploded after the predetermined time after the propellant is ignited to explode A projectile equipped with a dispersal bomb and a high explosive.
The method according to claim 8,
The high explosive detonator,
One end side is mounted on the rear side of the fuse part and is fixed, and the other propellant tube member is connected to the other end, and the first detonation tube passage hole through which the propellant ignition detonation tube part penetrates in the longitudinal direction and is opened to the side and the first detonation An ignition block body in which a second air passage tube through hole connecting the tube passage hole and the high explosive charge filling space is located;
A first ignition retarder positioned in the first through-hole of the detonator and surrounding an outer surface of the detonator to ignite the propellant;
A second ignition retardant protruding from the first ignition retardant and positioned in the second aeration tube through-hole; And
And a high explosive detonation tube portion for detonating from the second ignition retarder to detonate the high explosive charge part.
The method according to claim 9,
And the second ignition retardant is filled in a portion in the second detonation tube through-hole, and the high-expansion detonation tube portion is positioned to fill the remaining portion of the second detonation tube through-hole and to contact the high-expanding chemicals. A projectile equipped with a dispersal bomb and a high explosive.
The method according to claim 9,
And the first ignition retardant is formed to have a size covering the outer surface of the propellant ignition detonator tube and covering the first through hole of the first detonator.
delete

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