KR20210061012A - Independent Self-Destruct Fuse of Submunition with Shelf Safety in Assembling Process - Google Patents

Abstract

The present invention relates to an independent type self-detonation device of a stray bullet capable of increasing safety in an assembly process. In accordance with the present invention, a structure of a slider assembly is improved to remove an operation risk of an independent-type self-detonation device caused by separating a locking ball by strong rotation of a slider body in a direction of a side surface or separation of an auxiliary pin, caused by locking of an auxiliary pin wing part or careless handling between processes. The independent-type self-detonation device of a stray bullet comprises: an auxiliary detonator to detonate a main detonator when the main detonator is not detonated normally; a striker installed to be able to rotate on a slider body by a striker pin to detonate the auxiliary detonator; a safety pin partially inserted into a groove of the striker after passing through the slider body and restraining the striker from rotating; an auxiliary pin for withstanding an elastic restoring force of a striker spring compressed, when the safety pin is removed; a locking ball for filling a space between the auxiliary pin and the striker to constrain the rotation of the striker; and an auxiliary tape deployed due to air resistance when a stray bullet is free-falling so that the auxiliary pin is removed from the slider body. Moreover, by limiting rotation of the auxiliary pin, only when the auxiliary pin is separated in a direction perpendicular to the slider body, the locking ball comes out and a striker is able to rotate. To this end, a protrusion for locking an auxiliary pin is formed to allow an auxiliary pin wing part to be locked by an upper surface of the slider body.

Description

Independent Self-Destruct Fuse of Submunition with Shelf Safety in Assembling Process

The present invention relates to an independent self-destruction device for a grenade with increased safety between assembly processes, and more particularly, by improving the structure of the slider assembly, the auxiliary pin is separated due to careless handling or jamming of the auxiliary pin wing portion between processes. It relates to a stand-alone self-destruction device of a grenade, which eliminates the risk of operation of an independent self-destruction device caused by repelling the locking ball by being strongly rotated in the lateral direction of the slider body, and further increasing the safety in the assembly process.

In general, grenades transported from the ground by a carrier (motan) such as a gun or rocket are filled with high explosives inside the shell, and a penetrator for penetrating armor such as an armored vehicle or tank is installed in the lower part of the grenade. It is used for dual purposes such as killing and armor penetration.

When these grenades reach a predetermined sky by the carrier (motan), they are released into the atmosphere by the explosion pressure generated by the explosion of the discharge charge provided inside the carrier and fall to the ground. And each grenade is scattered in all directions by the inertia it had at the time of release, falling to the ground and exploding.

On the other hand, a conventional grenade 100, as shown in Fig. 1, is made by mounting a conical penetrator 404 on the charcoal body 402 filled with high explosives 403 therein, and a connection pipe ( A charitable body assembly 400 provided with 401; A slider assembly 300 having a periodic width pipe 301 and a loading spring 312 for detonating the high explosives 403; The sunken screw 202 that detonates the high explosive powder 403 by a ground drop impact and fixes the slider assembly 300 by tightening the screw, and the sunk screw 202 is deployed under air resistance when the charcoal is released from the motan. It includes a main tape 201 for releasing the restraint of the slider assembly 300 and an inertial weight 203 that is integrally coupled to the sunk screw 202 to increase its own weight and impart an inertial force, and the magnetite body assembly 400 A fuse assembly 200 coupled to the upper part of the ); It includes.

When the main tape 201 of the fuse assembly 200 is unfolded by the air resistance of the grenade 100 of the above configuration, the sunk screw 202 is released, and the slider assembly by the sunk screw 202 ( The restraint of the 300 is released, and the slider assembly 300 moves forward by the loading spring 312 to perform loading. For this reason, the explosive series is arranged in the order of the sinking screw 202, the periodic width pipe 301, and the connection pipe 401, and the moment the grenade 100 falls to the ground and collides, the weight of the inertial weight 203 The sinking screw 202 detonates the periodic width pipe 301, so that the high explosive powder 403 is finally exploded. Therefore, the charcoal body assembly 400 is fragmented to cause human death, and at the same time, the explosive force is concentrated to one place by the penetrator 404 provided in the charcoal body assembly 400 to penetrate the armor. do.

However, when the grenade 100 is released from the air and collides with a structure on the ground, if it is caught in an area that is not sufficiently impacted such as grass, snow, mud, sand, or an obstacle high from the ground, such as a tree, the sunk screw The inertial force when 202 hits the periodic width pipe 301 is buffered, or the sinking screw 202 cannot hit the periodic width tube 301 at all, so that the periodic width tube 301 is not detonated. There is a problem of causing physical damage to allies in the operation due to the occurrence of unexploded grenade.

Accordingly, in order to solve the misfire problem of the grenade 100, when it is impossible to detonate the periodic width pipe 301 by the sunk screw 202, the generation of the misfired grenade by detonating the periodic width pipe 301 using an auxiliary detonation tube A technology for self-destruction of a grenade has been developed, and as a related technology, for example, the applicant's Patent No. 10-0306357 (Patent Document 1), Patent No. 10-1078153 (Patent Document 2), and Patent No. There are 10-1519387 (Patent Document 3) and Patent No. 10-1541592 (Patent Document 4).

The independent self-destruction device of the grenade disclosed in these patent documents, as shown in Figs. 2 and 3, the auxiliary detonation pipe 302 for detonating the periodic width pipe 301 when the periodic width pipe 301 is not normally detonated, and , Delay pipe 308, which is formed in a U shape to extend the delay time required for self-destruction, connects the auxiliary detonation pipe 302 and the periodic width pipe 301, and is accommodated in the slider body 303, and the slider body 303 A slider stopper 309 that is coupled to one side of the delay pipe 308 to prevent separation, and a striker pin 306 ′ on the other side of the slider body 303 is rotatably installed to provide an auxiliary detonator pipe 302. A striker 306 to detonate, a safety pin 310 that is partially inserted into the groove of the striker 306 after passing through the slider body 303 to restrict the striker 306 from rotating between assembly processes, and a grenade ( When 100) falls freely, it fills the space between the auxiliary tape 205 and the auxiliary pin 204 and the striker 306 so that the auxiliary pin 204 is separated from the slider assembly 300 while being developed by air resistance. When the safety pin 310 is removed, a locking ball 307 that helps restrain the striker 306, a tape support pin 206 connecting the auxiliary pin 204 and the auxiliary tape 205, and the striker 306 are connected. A striker spring 304 providing an elastic force for rotation, a pusher 305 inserted into the striker spring 304 to push the striker 306 to rotate when the striker 306 is released from the restraint, and a delay pipe ( 308) and a support pin 311 for preventing the slider stopper 309 from being separated.

On the other hand, in the conventional grenade 100 having an independent self-destruction device, as shown in FIG. 4, a locking ball filling the space between the striker 306 and the auxiliary pin 204 in the conventional slider assembly 300 ( 307), the auxiliary pin 204 is removed due to careless handling during the (assembly) process or the auxiliary pin wing portion 204' is jammed, or the auxiliary pin wing portion 204' in the lateral direction of the slider body 303 When rotated, the self-destruct function is operated by being bounced off by the elastic restoring force of the striker spring 304.

Patent Document 1: KR 10-0306357 B1 Patent Document 2: KR 10-1078153 B1 Patent Document 3: KR 10-1519387 B1 Patent Document 4: KR 10-1541592 B1

The present invention was conceived to solve the problems of the prior art, and by improving the structure of the slider assembly, the auxiliary pin is separated or assisted in the side direction of the slider body due to careless handling between processes or jamming of the auxiliary pin wing. When the pin blade is rotated, the risk of operation of the independent self-destruction device caused by the locking ball filling the space between the striker and the auxiliary pin in the slider assembly is repelled by the elastic restoring force of the striker spring. It is an object to provide a standalone self-destruction device for increased grenade.

The present invention for achieving the above object is an auxiliary detonator tube for detonating the periodic tube when the periodic tube is not normally detonated, a striker rotatably installed on the slider body by a striker pin to detonate the auxiliary detonation tube, and a slider A safety pin that is partially inserted into the groove of the striker after passing through the body to constrain the striker from rotating, and an auxiliary pin that withstands the elastic restoring force of the compressed striker spring when the safety pin is removed, and prevents the striker from rotating; A standalone type of grenade that includes a locking ball that fills the space between the striker and the auxiliary pin to help confine the striker, and an auxiliary tape that allows the auxiliary pin to be separated from the slider body while being deployed by air resistance when the grenade is discharged from the grenade. In the self-destruction device,

In order to limit the rotation of the auxiliary pin, the fixed angle between the side surface of the slider body and the reference surface of the auxiliary pin blade is kept constant, so that the auxiliary pin can only be removed in the direction perpendicular to the slider body. , The auxiliary pin is characterized in that the protrusion is formed for locking the auxiliary pin wing portion.

In addition, the auxiliary pin engaging protrusion is characterized in that it is formed on the outer edge of the striker, compared to the rotation axis of the striker so as to secure a fixed angle between the side surface of the slider body and the reference surface of the auxiliary pin wing.

In addition, the protrusion for locking the auxiliary pin is characterized in that it is formed in a cylindrical structure of the lower gwangsanghyup (下廣上狹) to facilitate the vertical separation of the auxiliary pin.

In addition, the auxiliary pin wing portion is characterized in that the lower portion is formed to have a thickness that spans at least the middle portion of the auxiliary pin engaging projection.

The independent self-destruction device of the grenade with increased safety during the assembly process of the present invention has a striker that detonates an auxiliary detonator, and a protrusion for locking an auxiliary pin is formed on the upper surface of the slider body on which an auxiliary pin and a locking ball are installed to restrain the striker. As a result, the rotation of the auxiliary pin is blocked due to interference with the auxiliary pin wing, so that the auxiliary pin is removed from the slider body only when it is moved upward in the vertical direction, and in other cases, the auxiliary pin does not come out of the slider body so that the striker cannot rotate. There is an effect.

Accordingly, the locking ball, which helps to restrict the rotation of the striker by filling the space between the striker and the auxiliary pin in the conventional slider assembly, is removed from the auxiliary pin due to careless handling or jamming of the auxiliary pin blade portion during the process. In order to prevent bouncing while strongly rotating in the lateral direction of the body, the fixed angle between the side of the slider body and the reference surface of the auxiliary pin wing is kept constant, so that the separation of the locking ball does not occur. There is an effect that the self-destruct function that occurs by hitting the width pipe does not work, so that unexpected safety accidents can be prevented.

1 is a longitudinal sectional view showing a free fall state of a general grenade.
2 is an exploded perspective view of a conventional slider assembly.
Figure 3 is an exploded perspective view of a conventional fuse assembly provided with an independent self-destruction device.
Figure 4 is a reference view showing a state in which the locking ball is separated by strong rotation due to the locking of the auxiliary pin wing in the conventional slider assembly.
5 is a perspective view and a plan view showing a slider assembly of an independent self-destruction device of a grenade with increased safety between assembly processes according to the present invention.
6 is an exploded perspective view of the slider assembly according to the present invention.
7 is a reference view showing a state in which the auxiliary pin is not rotated because the auxiliary pin wing portion is caught on the auxiliary pin engaging protrusion in the slider assembly according to the present invention.
Figure 8 is a reference view showing a structure in which the separation of the locking ball is prevented by maintaining a fixed angle between the side surface of the slide body and the reference surface of the auxiliary pin wing in the slider assembly according to the present invention.
9 is an exploded perspective view of a fuse assembly provided with an independent self-destruction device for a grenade with increased safety between assembly processes according to the present invention.

Hereinafter, with reference to the accompanying drawings, a description will be given of the self-destruction apparatus of a grenade with increased safety between assembly processes of the present invention.

In the accompanying drawings, FIG. 5 is a perspective view and a plan view showing a slider assembly of an independent self-destruction device for a grenade with increased safety between assembly processes according to a preferred embodiment of the present invention, and FIG. 6 is an exploded perspective view of the slider assembly according to the present invention. 7 is a reference view showing a state in which the auxiliary pin wing portion is hung on the auxiliary pin engaging protrusion in the slider assembly according to the present invention, and FIG. 8 is a side view of the slider body and the auxiliary pin wing portion in the slider assembly according to the present invention. Reference diagram showing a structure in which the locking ball is prevented from being separated by maintaining a fixed angle between the reference planes, and FIG. 9 is a disassembly of a fuse assembly equipped with an independent self-destruction device for a grenade with increased safety between assembly processes according to the present invention. It is a perspective view.

On the other hand, in the following description based on the accompanying drawings, detailed descriptions of known technologies that may unnecessarily obscure the subject matter of the present invention are omitted, and duplicated by denoting the same reference numerals for the same parts as in the prior art. The explanation will be omitted.

The independent self-destruction device of a grenade with increased safety between assembly processes according to the present invention is provided in the slider assembly 300 to which the fuse assembly 200 is coupled, as shown in FIGS. 1 and 5 to 9.

That is, the independent self-destruction device of the grenade with increased safety between assembly processes of the present invention includes an auxiliary detonation pipe 302 for detonating the periodic width pipe 301 when the periodic width pipe 301 is not normally detonated, and the auxiliary detonation pipe 302 required for self-destruction. A delay tube 308 that is formed in a U shape to extend the delay time and connects the auxiliary detonation tube 302 and the periodic width tube 301 and is accommodated in the slider body 303, and one side of the slider body 303 A slider stopper 309 that is coupled to the delay pipe 308 to prevent separation, and a striker pin 306' on the other side of the slider body 303 are rotatably installed to detonate the auxiliary detonator pipe 302. After passing through the striker 306, the striker spring 304 providing elastic force to rotate the striker 306, and the slider body 303, a part is inserted into the groove of the striker 306 so that the striker 306 is When the safety pin 310 to prevent rotation, the auxiliary pin 204 to withstand the elastic restoring force of the striker spring 304 compressed when the safety pin 310 is removed, and the grenade 100 free fall It is developed by the air resistance of the auxiliary tape 205 to allow the auxiliary pin 204 to be removed from the slider body 303, and the auxiliary pin 204 and the auxiliary pin 204 by filling the space between the auxiliary pin 204 and the striker 306 A locking ball 307 for restraining the striker 306 together, a tape support pin 206 connecting the auxiliary pin 204 and the auxiliary tape 205, and the auxiliary pin 204 inserted into the striker spring 304 A pusher 305 that pushes the striker 306 to rotate when it is removed from the slider body 303, a support pin 311 for preventing separation of the delay pipe 308 and the slider stopper 309, and an auxiliary pin ( An auxiliary pin formed on the upper surface of the slider body 303 so that the auxiliary pin 204 is separated from the slider body 303 only in a vertical direction by limiting the rotation of the 204 so that the auxiliary pin wing portion 204' is caught. It includes a protrusion 500 for engaging.

Here, the auxiliary pin catching protrusion 500 is such that a fixed angle between the side surface of the slider body 303 and the reference surface of the auxiliary pin wing portion 204' is sufficiently, preferably 70° or more secured, of the striker 306 Compared to the rotating shaft, it is preferably formed on the outer edge. And it is preferable that the auxiliary pin engaging protrusion 500 is formed in a cylindrical structure with a wide bottom and a narrow top so that vertical separation of the auxiliary pin 204 is easy. In addition, the auxiliary pin wing portion 204 ′ formed integrally with the auxiliary pin 204 is preferably formed to have a thickness that extends at least over the middle portion of the auxiliary pin engaging protrusion 500.

In this way, when the auxiliary pin locking projection 500 is formed on the slider body 303, as shown in FIG. 7, the auxiliary pin wing portion 204 ′ is caught on the auxiliary pin locking projection 500. Therefore, as shown in Figure 8, regardless of the elastic restoring force of the striker spring 304 pushes the pusher 305, the side surface of the slider body 303 and the reference surface of the auxiliary pin wing portion 204' The fixed angle between them is kept constant. Therefore, as long as the auxiliary pin 204 moves in the vertical direction from the slider body 303 and does not separate due to the expansion of the auxiliary tape 205 due to air resistance, the striker 306 is not restricted because the striker 306 is not released. It becomes impossible to hit the auxiliary detonator 302.

Accordingly, the locking ball 307 which helps to restrain the rotation of the striker 306 by filling the space between the striker 306 and the auxiliary pin 204 in the slider assembly 300, The side of the slider body 303 and the auxiliary pin wing portion ( By maintaining a fixed angle between the reference planes of 204'), the separation of the locking ball 307 does not occur, and thus, the self-destruction function generated by the striker 306 hitting the auxiliary detonator tube 302 does not operate. As a result, unexpected safety accidents can be prevented.

As described above, embodiments illustrating the technical idea of the present invention have been described based on the accompanying drawings, but the present invention is not limited to the configuration and operation as described above, without departing from the scope of the technical idea described in the claims. , It will be well understood by those skilled in the art that a number of changes and modifications may be made to the present invention. Accordingly, all such appropriate changes and modifications and equivalents should be considered to be within the scope of the present invention.

100... Grenade
200… Fuse assembly
201... Jute tape
202... Sunk screw
203... Inertial weight
204... Auxiliary pin
204'... Auxiliary pin wing
205... Auxiliary tape
206... Tape support pin
300… Slider assembly
301... Periodic width pipe
302... Auxiliary detonator
303... Slider body
304... Striker spring
305... Pusher
306... Striker
306'... Striker pin
307... Rocking ball
308... Delay tube
309... Slider stopper
310... safety pin
311... Support pin
312... Loading spring
400… Charan body assembly
401... Connector
402... Charan body
403... High explosive powder
404... Penetrator
500… Auxiliary pin jamming protrusion

Claims (4)

In case the periodic tube is not detonated normally, an auxiliary detonating tube to detonate the main detonating tube, a striker rotatably installed on the slider body by a striker pin to detonate the auxiliary detonating tube, and a part of the groove of the striker after passing through the slider body A safety pin that is inserted to prevent the striker from rotating, an auxiliary pin that withstands the elastic restoring force of the striker spring that was compressed when the safety pin is removed, and the space between the auxiliary pin and the striker is used to constrain the rotation of the striker. In the stand-alone self-destruction device of a grenade comprising a locking ball that helps the grenade and an auxiliary tape that is developed by air resistance when the grenade falls freely so that the auxiliary pin is removed from the slider body,
By limiting the rotation of the auxiliary pin, the locking ball comes out and the striker can rotate only when the auxiliary pin is separated in a direction perpendicular to the slider body, and the fixed angle between the side of the slider body and the reference surface of the auxiliary pin wing is kept constant. An independent self-destruction device for grenade with increased safety between assembly processes, characterized in that a protrusion for locking an auxiliary pin to hold is formed. The method according to claim 1,
The auxiliary pin catching protrusion is formed on the outer edge of the striker compared to the rotation axis of the striker so that a fixed angle between the side surface of the slider body and the reference surface of the auxiliary pin blade is secured. Standalone self-destruction device. The method according to claim 1,
An independent self-destruction device for grenade with increased safety between assembly processes, characterized in that the protrusion for locking the auxiliary pin is formed in a cylindrical structure with a wide bottom and a narrow top to facilitate vertical separation of the auxiliary pin. The method according to claim 1,
The auxiliary pin wing portion, the lower portion, the stand-alone self-destruction device of the grenade with increased safety between the assembly process, characterized in that the thickness is formed over at least a middle portion of the auxiliary pin engaging projection.

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