KR102124079B1 - Non electric explosive bolt and separating apparatus for projectile using the same - Google Patents

Abstract

The present invention relates to a non-electrical ignition device which comprises a main charge portion for explosion located therein, a bolt body member with a threaded portion on the outer circumferential surface, and a plurality of flame holes positioned on the other end side of the bolt body member to allow the flame in a launch tube to flow inside, so as to be exploded by the flame flowing inside through the plurality of flame holes, to secure the economic feasibility because of the simple manufacturing process and the low manufacturing cost compared to the existing electric explosive bolt, thereby preventing accidental shootings caused by short circuits of electric cables, stably firing the projectile, and allowing the projectile to accurately hit a target.

Description

Non-electric explosive bolt and projectile separation device using the same{NON ELECTRIC EXPLOSIVE BOLT AND SEPARATING APPARATUS FOR PROJECTILE USING THE SAME}

The present invention relates to a non-electric explosive bolt and a projectile separation device using the same, and more particularly, an invention relating to a non-electric explosive bolt capable of separating a projectile from a launch tube by receiving a flame within the launch tube and a projectile separation device using the same .

In general, projectiles such as missiles or missiles, which are guided by a specific method until the target is reached, are kept in the launcher until they are fired.

Projectiles such as bullets stored in the launch tube are fired separately from the launch tube according to the firing command during an operation during movement.

Projectiles, such as guided munitions, stored in the launcher must be firmly constrained to be positioned without flow in the launcher while on the move.

That is, projectiles such as guided missiles must be stably restrained without movement in the launch tube by a load acting from the outside during movement for safety, and they must be quickly and reliably separated from the launch tube during launch to be highly reliable and stable to launch within the launch tube. do.

Accordingly, projectiles such as guided ammunition are confined in the launch tube by using an explosive bolt that charges a certain portion of the bolt and cuts it into a shock wave using the explosive power of the explosive.

That is, the explosive bolt is fastened to the connecting part of the projectile and the launch tube in the launch tube to securely fix the projectile until the launch.

In addition, the explosive bolt is exploded in response to an explosive signal when the projectile is launched, so that the projectile is quickly and accurately separated from the launch tube so that the projectile can be smoothly fired in the launch tube.

As a conventional explosive bolt, there is'explosive bolt' (1994.12.27.) of Korean Patent No. 0084170.

'Explosive bolt' of Korean Patent No. 0084170 installs a separate powder and a detonator inside the bolt body, and as an electrical signal is applied to the detonator through a lead wire, the explosion of the detonated explosives occurs due to the operation of the detonator. ) Is configured to cause separation along the separation line.

However, the conventional explosive bolt has an electric detonator, that is, an electrical primer and a lead wire for applying an electrical signal to the electrical primer to explode the explosive bolt by applying an electrical signal through the lead wire to the explosive bolt, so the manufacturing process is complicated. And, there was a problem that a lot of manufacturing cost.

In addition, the conventional explosive bolt is a short circuit of the lead wire that applies an electrical signal or when the electrical detonator malfunctions, the explosive bolt is not exploded when the projectile is fired. There was a problem that the projectile could not be fired smoothly.

In addition, if the projectile does not fire smoothly, there is a problem that the target target point cannot be accurately hit, and there is a risk of causing a large accident due to the projectile misfire.

0001)'Explosive bolt' of Korean Patent No. 0084170 (Dec. 27, 1994)

An object of the present invention is to provide a non-electric explosive bolt and a projectile separation device using the same, which have a simpler manufacturing process than the conventional electric explosive bolt, and thus require less manufacturing cost.

Another object of the present invention is to prevent the occurrence of malfunction by igniting and exploding with a high-pressure flame generated in the launch tube when the projectile is fired, and the non-electric explosive bolt capable of stably separating the projectile from the launch tube and separating the projectile using the same In providing the device.

In order to achieve the above object of the present invention, an embodiment of the non-electric explosion bolt according to the present invention includes a bolt body member in which an assertion weak portion for explosion is located inside and a threaded portion is located on an outer circumferential surface, wherein the bolt body On the other end side of the member, a plurality of flame holes are positioned to allow the flame in the launch tube to flow inside, and it is characterized in that the flame is exploded by the flame introduced into the inside through the plurality of flame holes.

In the present invention, the bolt body member is a bolt portion where a thread portion is located on an outer circumferential surface, an extension portion is located on one side of the bolt portion, and an explosive storage space is located inside, so that the breakage portion and the break portion that break when the claimed medicine portion is exploded. It may include a flame inlet having a plurality of flame holes spaced apart from each other in a lengthwise direction, and a flame movement passage connected to the powder storage space in the longitudinal direction and spaced apart in the longitudinal direction.

In the present invention, a notched groove portion for cutting the bolt body member into two parts may be located on the outer circumferential surface of the breaking portion.

In the present invention, the flame inlet portion may have a larger diameter than the fracture portion.

In the present invention, in the gunpowder storage space, a main ignition drug unit for igniting the claim medicine unit may be located on the other side of the claim medicine unit.

In the present invention, a plurality of flame holes are formed to be spaced apart in the longitudinal direction, and a plurality of flame holes are formed to be spaced apart in the circumferential direction on the outer circumferential surface of the flame inlet.

In the present invention, a flame guide tube member is located in the flame movement passage of the flame inlet, and the flame guide tube member is located with a flame guide flow path for guiding the flame and introducing the introduced flame to the main ignition weakener, and having a length on the outer circumferential surface. In the direction, a plurality of auxiliary flame holes connected to the flame guide channel part may be positioned.

In the present invention, the flame movement passage includes a first flame flow path portion having the same diameter as the gunpowder storage space, and a second flame flow path portion formed to a larger diameter than the first flame flow path portion, and the flame guide tube member comprises the first A first guide tube portion located in the one flame flow path portion and having a first flame guide flow path portion in a longitudinal direction therein; And a second flame guide flow path portion connected to the first flame guide flow path portion in the longitudinal direction, and a plurality of auxiliary flame holes connected to the second flame guide flow path portion spaced apart in the longitudinal direction on the outer circumferential surface. It may include a guide tube.

In the present invention, a protruding portion for pipe support may be located at one end side of the second guide tube portion to protrude toward the outer circumferential surface and be inserted into the first flame flow path portion to separate the first flame flow path portion and the outer circumferential surface of the second guide pipe portion. have.

In the present invention, the flame hole includes a plurality of first flame holes located in the first flame flow path portion, and a plurality of second flame holes located in the second flame flow path portion, and the auxiliary flame hole includes a plurality of the It may include a plurality of first auxiliary flame holes corresponding to the first flame hole, a plurality of second auxiliary flame holes positioned to correspond to the plurality of second flame holes.

In the present invention, the first flame guide flow path portion is a linear guide flow path located in the longitudinal direction of the first guide pipe portion, and is located at an end side of the straight guide flow path and gradually increases in diameter toward the end side of the first guide pipe portion. It may include a cone-shaped cone inlet, and the second flame guide channel portion may have a straight channel shape having a diameter larger than the diameter of the linear guide channel and a diameter smaller than the final diameter of the cone inlet.

In the present invention, the other end side of the flame guide tube member is connected to an auxiliary ignition weak portion located at the end side of the flame inlet, and the auxiliary ignition weak portion is ignited by a flame introduced into the second flame guide channel portion to prevent a flame. Can be amplified.

In order to achieve the above object of the present invention, an embodiment of a projectile separating device according to the present invention is a projectile fixing member mounted on a launch tube and fixed, a projectile fixing member positioned to protrude on an outer circumferential surface of the projectile and coupled with the launch tube fixing member , A non-electric explosive bolt that penetrates the launch tube fixing member and is fastened to the projectile fixing member to fix the projectile to the launch tube, wherein the non-electric explosive bolt is ignited by a flame in the launch tube and separated into at least two bodies. It characterized in that the separation between the launch tube fixing member and the projectile fixing member.

In the present invention, the non-electric explosion bolt includes a bolt body member in which a captive weak portion for explosion is located inside and a screw thread portion is located on the outer circumferential surface, and a plurality of the flame inside the launch tube is introduced into the other end of the bolt body member. The flame hole of the is located may explode by the flame introduced into the inside through a plurality of flame holes.

In the present invention, the bolt body member is a bolt portion where a thread portion is located on an outer circumferential surface, an extension portion is located on one side of the bolt portion, and an explosive storage space is located inside, so that the breakage portion and the break portion that break when the claimed medicine portion is exploded. It may include a flame inlet having a plurality of flame holes spaced apart from each other in a lengthwise direction, and a flame movement passage connected to the powder storage space in the longitudinal direction and spaced apart in the longitudinal direction.

In the present invention, a notched groove portion for cutting the bolt body member into two parts may be located on the outer circumferential surface of the breaking portion.

In the present invention, the flame inlet portion may have a larger diameter than the fracture portion.

In the present invention, in the gunpowder storage space, a main ignition drug unit for igniting the claim medicine unit may be located on the other side of the claim medicine unit.

In the present invention, a plurality of flame holes are formed to be spaced apart in the longitudinal direction, and a plurality of flame holes are formed to be spaced apart in the circumferential direction on the outer circumferential surface of the flame inlet.

In the present invention, a flame guide tube member is located in the flame movement passage of the flame inlet, and the flame guide tube member is located with a flame guide flow path for guiding the flame and introducing the introduced flame to the main ignition weakener, and having a length on the outer circumferential surface. In the direction, a plurality of auxiliary flame holes connected to the flame guide channel part may be positioned.

In the present invention, the flame movement passage includes a first flame flow path portion having the same diameter as the gunpowder storage space, and a second flame flow path portion formed to a larger diameter than the first flame flow path portion, and the flame guide tube member comprises the first A first guide tube portion positioned in the first flame passage portion and having a first flame guide flow path portion in a longitudinal direction therein, and a second flame guide flow path portion connected to the first flame guide flow path portion positioned in the longitudinal direction, and the second A plurality of auxiliary flame holes connected to the flame guide flow path part may include a second guide tube part spaced apart in the longitudinal direction on the outer circumferential surface.

In the present invention, a protruding portion for pipe support may be located at one end side of the second guide tube portion to protrude toward the outer circumferential surface and be inserted into the first flame flow path portion to separate the first flame flow path portion and the outer circumferential surface of the second guide pipe portion. have.

In the present invention, the flame hole includes a plurality of first flame holes located in the first flame flow path portion, and a plurality of second flame holes located in the second flame flow path portion, and the auxiliary flame hole includes a plurality of the It may include a plurality of first auxiliary flame holes corresponding to the first flame hole, a plurality of second auxiliary flame holes positioned to correspond to the plurality of second flame holes.

In the present invention, the first flame guide flow path portion is a linear guide flow path located in the longitudinal direction of the first guide pipe portion, and is located at an end side of the straight guide flow path and gradually increases in diameter toward the end side of the first guide pipe portion. It may include a cone-shaped cone inlet, and the second flame guide channel portion may have a straight channel shape having a diameter larger than the diameter of the linear guide channel and a diameter smaller than the final diameter of the cone inlet.

In the present invention, the other end side of the flame guide tube member is connected to an auxiliary ignition weak portion located at the end side of the flame inlet, and the auxiliary ignition weak portion is ignited by a flame introduced into the second flame guide channel portion to prevent a flame. Can be amplified.

In the present invention, the launch tube fixing member may be replaced by a bolt fastening to the launch tube when damaged by the explosion of the non-electric explosion bolt.

In the present invention, a fixed support protrusion is protruded on an inner circumferential surface of the launch tube, and the launch tube fixing member is bolted to the fixed support protrusion to support an upper surface of the projectile fixing member.

The present invention has an effect of securing economic efficiency as the manufacturing process is simple compared to the existing electric explosive bolt, and thus the manufacturing cost is low.

The present invention has an effect of preventing accidents caused by a short circuit of an electric wire, stably firing a projectile, and accurately projecting a projectile.

1 is a cross-sectional view showing an embodiment of a non-electric explosion bolt according to the present invention.
Figure 2 is a perspective view showing an embodiment of a projectile separation device including a non-electric explosion bolt according to the present invention.
3 is an enlarged perspective view showing an embodiment of a projectile separation device including a non-electric explosion bolt according to the present invention.
Figure 4 is an enlarged cross-sectional view showing an embodiment of a projectile separation device including a non-electric explosion bolt according to the present invention.

The present invention will be described in more detail.

If described in detail by the accompanying drawings, preferred embodiments of the present invention. Prior to the detailed description of the present invention, terms or words used in the present specification and claims described below should not be interpreted as being limited to a conventional or dictionary meaning. Therefore, the configuration shown in the embodiments and drawings described in this specification are only the most preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, and thus can replace them at the time of application. It should be understood that there may be equivalents and variations.

1 is a cross-sectional view showing an embodiment of the non-electric explosive bolt 300 according to the present invention, referring to FIG. 1, the non-electric explosive bolt 300 according to the present invention is a bolt body member with a threaded portion located on its outer circumferential surface 310.

Inside the bolt body member 310, there is a gunpowder storage space 331 in which the claim medicine unit 360 for explosion may be located.

One side of the gunpowder storage space 331 is blocked, the other side is an open space, and the claim medicine part 360 is located at one end of the gunpowder storage space 331.

As an example, the bolt body member 310 is provided with a bolt portion 320 in which a thread portion is located on an outer circumferential surface on the front end side.

The bolt body member 310 is located on the outer circumferential surface of the bolt portion 320, the bolt portion 320 is extended to one side is located and the inside of the gunpowder storage space 331 is located in the case of the explosion of the claimed drug 360 The rupture portion 330 to be broken, a flame movement path 342 extending to one side of the rupture portion 330 and connected to the gunpowder storage space 331 in the longitudinal direction is positioned and spaced apart in the longitudinal direction. It includes a flame inlet 340 where the flame hole 341 is located.

On the outer circumferential surface of the breaking portion 330, a notch groove portion 332 is provided to facilitate cutting the bolt body member 310 into two parts.

The notched groove portion 332 is formed in a groove shape surrounding the claimed medicine portion 360 in the broken portion 330 so that the broken portion 330 can be reliably cut into two parts by the explosion of the claimed medicine portion 360.

As an example, the flame inlet part 340 has a larger diameter than the fracture part 330.

In addition, the main ignition medicament unit 370 for igniting the claim medicament unit 360 is located on the other side of the claim medicament unit 360 in the gunpowder storage space 331.

The main ignition weak portion 370 is positioned in close contact with the assertion weak portion 360 on the other side of the assertion weakening portion 360 to be ignited with a flame in the launch tube, and after being ignited, the assertion weakening portion 360 is ignited to explode.

A flame movement passage 342 connected to the gunpowder storage space 331 is located in the flame inlet 340.

The flame movement passage 342 is a space that is connected to the other end side of the explosive storage space 331 and is located in the longitudinal direction of the flame inlet 340.

A plurality of flame holes 341 are formed in the longitudinal direction on the outer circumferential surface of the flame inlet part 340, and a plurality of flame holes 341 formed spaced apart in the longitudinal direction are positioned to be spaced apart in the circumferential direction, thereby providing a flame inlet part 340. The flame can flow smoothly into the circumference of the inside.

The flame inlet passage 340 has a flame guide passage portion 351 in which flame is introduced and guides the introduced flame to the main ignition medicine portion 370, and a flame guide passage portion in the longitudinal direction on the outer circumferential surface of the flame inlet passage 340. 351) is a flame guide tube member 350 in which a plurality of auxiliary flame holes 352 are positioned.

The auxiliary flame hole 352 is positioned to correspond to the flame hole 341 so that the flame flowing into the flame hole 341 can be smoothly introduced into the flame flow path portion.

In addition, the flame movement passage 342 has a first flame flow path portion 342a having the same diameter as the gunpowder storage space 331, and a second flame flow path portion 342b formed with a larger diameter than the first flame flow path portion 342a. It includes.

The flame guide pipe member 350 is located in the first flame flow path portion 342a, and the first guide pipe portion 350a and the first flame guide flow path portion in which the first flame guide flow path portion 351a is positioned in the longitudinal direction therein. The second flame guide passage part 351b connected to the (351a) is located in the longitudinal direction, and a plurality of auxiliary flame holes 352 connected to the second flame guide passage part 351b are spaced apart in the longitudinal direction on the outer circumferential surface. It includes a second guide tube portion 350b located.

For the pipe support which protrudes to the outer circumferential surface at one end side of the second guide tube portion 350b and is inserted into the first flame flow path portion 342a to separate the outer circumferential surfaces of the first flame flow path portion 342a and the second guide pipe portion 350b. The protrusion 350c is located.

That is, the second guide tube portion 350b has a diameter smaller than that of the first flame flow path portion 342a and is located at the center of the first flame flow path portion 342a by the protrusion 350c for pipe support, so that the flame is inside the outer circumference. The gap that can be introduced into is located.

The flame hole 341 includes a plurality of first flame holes 341a positioned in the first flame flow path portion 342a and a plurality of second flame holes 341b positioned in the second flame flow path portion 342b. .

In addition, the auxiliary flame hole 352 is a plurality of first auxiliary flame holes 352a positioned to correspond to the plurality of first flame holes 341a, and a plurality of second flame holes 341b positioned to correspond to the And a second auxiliary flame hole 352b.

And, the first flame guide flow path portion 351a is a linear guide flow path located in the longitudinal direction of the first guide pipe portion 350a, and is located at the end side of the straight guide flow path and goes toward the end side of the first guide pipe portion 350a. It includes a cone-shaped cone inlet that gradually increases in diameter.

In addition, the second flame guide flow path portion 351b has a diameter larger than the diameter of the straight guide flow path and a straight flow path having a diameter smaller than the final diameter of the cone inlet.

In addition, the other end side of the flame guide tube member 350 is connected to the auxiliary ignition weak portion 380 located on the end side of the flame inlet 340.

Then, the auxiliary ignition weak portion 380 is ignited by the flame introduced into the second flame guide flow path portion 351b to amplify the flame.

The auxiliary ignition weak section 380 is ignited by the flame introduced into the second flame guide flow path section 351b to transfer the flame to the main ignition weak section 370 so that the main ignition weak section 370 is ignited more smoothly and quickly. Make it possible.

The high-pressure flame in the blast tube introduced into the flame movement passage 342 in the flame inlet 340 through the plurality of flame holes 341 is through the first auxiliary flame hole 352a and the second auxiliary flame hole 352b. The second flame guide flow path part (350b) flows into the second guide pipe part (350b) to ignite the auxiliary ignition weak part (380), and when the auxiliary ignition weak part (380) is ignited, a flame is added to the second flame guide flow passage part ( The amplified flame in 351b) is moved along the first flame guide flow path portion 351a and transferred to the ignition reverse portion to ignite the main ignition weak portion 370.

In addition, due to the ignition of the main ignition weak portion 370, the breakable portion 330 is cut while the captive medicine explodes, so that the bolt body member 310 is separated into at least two parts.

At this time, the first flame guide flow path part 351a is through a cone inlet having a larger diameter inlet than the second flame guide flow path part 351b and a straight guide flow path having a smaller diameter than the second flame guide flow path part 351b. The amplified flame in the second flame guide flow path portion 351b can be delivered to the main ignition weak portion 370 as quickly and as quickly as possible.

2 is a perspective view showing an embodiment of a projectile separation device including a non-electric explosive bolt 300 according to the present invention, Figure 3 is a projectile separation device including a non-electric explosive bolt 300 according to the present invention An enlarged perspective view showing an embodiment, Figure 4 is an enlarged cross-sectional view showing an embodiment of a projectile separation device including a non-electric explosion bolt 300 according to the present invention.

Referring to Figures 2 to 4, an embodiment of the projectile separation device according to the present invention is mounted on the launch tube 10 and fixed to the launch tube fixing member 100 and the projectile 20 located in the launch tube 10. A projectile fixing member positioned protrudingly and coupled with the launch tube fixing member 100, a non-electric explosive bolt 300 that penetrates through the launch tube fixing member 100 and is fastened to the projectile fixing member to fix the projectile 20 to the launch tube 10. ), the non-electric explosive bolt 300 is ignited by a flame in the launch tube 10 and separated into at least two bodies to separate the launch tube fixing member 100 and the projectile fixing member.

The non-electric explosive bolt 300 includes a bolt body member 310 in which a captive weak portion 360 for explosion is located inside and a thread portion is located on an outer circumferential surface, and a launch tube 10 is provided at the other end side of the bolt body member 310. ) A plurality of flame holes 341 are positioned to allow the flames to flow into the interior, and the flames explode due to the flames introduced into the flame holes 341.

It is noted that the non-electric explosive bolt 300 may be implemented in the same manner as the non-electric explosive bolt 300 according to the present invention described above, and thus is omitted as a duplicate description.

The launch tube fixing member 100 is spaced apart in the circumferential direction on the inner circumferential surface of the launch tube 10, and the projectile fixing member is spaced apart in the circumferential direction on the outer surface of the projectile 20 to correspond to the launch tube fixing member 100. It is located in plural.

In addition, the launch tube fixing member 100 is mounted on the launch tube 10 by fastening bolts, and can be replaced when damaged by an explosion of an explosive bolt.

In the launch tube fixing member 100, a bolt body member 310 of the explosion bolt, that is, a bolt penetration part 110 through which the bolt part 320 and the breaking part 330 are penetrated and coupled is positioned.

In addition, the projectile fixing member is positioned to correspond to the bolt through portion 110 and the bolt fastening portion 210 to which the bolt portion 320 is inserted and fastened is located.

On the inner circumferential surface of the launch tube 10, the launch tube fixing member 100 is bolted, and a fixed support protrusion supporting the upper surface of the projectile fixing member 200 is protruded.

The fixed support protrusion increases the thickness of the launch tube 10 to prevent damage to the launch tube 10 when the explosion bolt explodes, and supports the positions of the launch tube fixing member 100 and the projectile fixing member 200 together to projectile 20 ) To be stably positioned within the launch tube 10.

That is, the main ignition weak section 370 is ignited when the high-pressure flame generated in the launch tube 10 flows into the inside through the flame hole 341 when the non-electric explosion bolt 300 is launched. As the 360 explodes, the rupture part 330 is separated into at least two bodies, and the launch tube fixing member 100 and the projectile fixing member 200 are separated from each other to finally separate the projectile 20 from the launch tube.

In more detail, when the projectile 20 is launched in the launch tube, high-pressure flame is generated in the launch tube and the high-pressure flame is introduced into the flame movement passage 342 in the flame inlet 340 through the plurality of flame holes 341. Inflow.

The flame introduced into the flame movement passage 342 flows back into the second flame guide flow path part 351b in the second guide pipe part 350b through the first auxiliary flame hole 352a and the second auxiliary flame hole 352b. The secondary ignition weak portion 380 is ignited, and as the secondary ignition weak portion 380 is ignited, the flame in the second flame guide flow path portion 351b is amplified and rapidly moves along the first flame guide flow path portion 351a. The ignition weak portion 370 is ignited.

Then, the ignition of the main ignition weak portion 370 causes the rupture portion 330 to be cut while the captive drug explodes, so that the bolt body member 310 is separated into at least two parts, whereby the launch tube fixing member 100 and projectile As the fixing member 200 is separated, the projectile 20 is finally separated from the launch tube so that it can be launched.

According to the present invention, the manufacturing process is simpler than the conventional electric explosive bolt, so manufacturing cost is low and economical efficiency is secured.

The present invention prevents accidents caused by a short circuit of the electric wire, stably fires the projectile 20, and allows the projectile 20 to accurately strike the target.

The present invention is not limited to the above-described embodiments, but can be carried out by variously changing within a range not departing from the gist of the present invention, and it is revealed that it is included in the configuration of the present invention.

10: launch tube 20: projectile
100: launch tube fixing member 110: bolt penetration
120: fixed support protrusion 200: projectile fixing member
210: bolt fastening part 300: non-electric explosion bolt
310: bolt body member 320: bolt portion
330: break 331: gunpowder storage space
332: notch groove 340: flame inlet
341: flame hole 341a: first flame hole
341b: Second flame hole 342: Flame passage
342a: 1st flame flow path part 342b: 2nd flame flow path part
350: flame guide tube member 350a: first guide tube
350b: second guide tube portion 350c: protrusion for pipe support
351: flame guide flow path section 351a: first flame guide flow path section
351b: 2nd flame guide flow path part 352: auxiliary flame hole
352a: 1st auxiliary flame hole 352b: 2nd auxiliary flame hole
360: Claim weak section 370: Main ignition weak section
380: auxiliary ignition weak

Claims (27)

Including the bolt body member in which the claim weak portion for explosion is located inside and the thread portion is located on the outer circumferential surface,
On the other end side of the bolt body member, a plurality of flame holes are positioned to allow the flame in the launch tube to flow into the inside, and the flame is exploded by the flame introduced into the flame holes.
The bolt body member,
A bolt portion in which a thread portion is located on the outer circumferential surface;
A rupture portion that extends on one side of the bolt portion and that has an explosive storage space located therein that breaks upon explosion of the captive medicine; And
It characterized in that it comprises a flame inlet portion is located extending from one side of the breaking portion and the flame movement passage is connected to the storage space in the longitudinal direction inside the plurality of flame holes are spaced apart in the longitudinal direction is located Electric explosion bolt.
delete The method according to claim 1,
Non-electric explosion bolt, characterized in that the notched groove for cutting the bolt body member into two parts on the outer circumferential surface of the breaking portion.
The method according to claim 1,
The flame inlet portion is a non-electric explosion bolt, characterized in that having a larger diameter than the breaking portion.
The method according to claim 1,
A non-electric explosive bolt, characterized in that a main ignition medicament for igniting the claim medicament is located on the other side of the claim medicament in the gunpowder storage space.
The method according to claim 5,
Non-electric explosion bolt, characterized in that a plurality of flame holes are formed to be spaced apart in the longitudinal direction, and a plurality of flame holes are formed to be spaced apart in the longitudinal direction on the outer circumferential surface of the flame inlet.
The method according to claim 5,
A flame guide tube member is located in the gunpowder movement passage of the flame inlet,
The flame guide tube member is a flame guide flow path portion for guiding the flame into the main ignition weak and the flame is introduced therein, and a plurality of auxiliary flame holes connected to the flame guide flow path portion in the longitudinal direction on the outer circumferential surface are located. It features a non-electric explosion bolt.
The method according to claim 7,
The flame movement passage includes a first flame flow path portion having the same diameter as the gunpowder storage space, and a second flame flow path portion formed with a larger diameter than the first flame flow path portion,
The flame guide pipe member is located in the first flame flow path portion, a first guide pipe portion in which a first flame guide flow path portion is located in a longitudinal direction therein; And
A second guide in which a second flame guide passage part connected to the first flame guide passage part is positioned in the longitudinal direction, and a plurality of auxiliary flame holes connected to the second flame guide passage part are spaced apart in the longitudinal direction on the outer circumferential surface. Non-electric explosion bolt, characterized in that it comprises a tube.
The method according to claim 8,
It characterized in that the protruding portion for pipe support is located on one end side of the second guide tube portion protruding toward the outer circumferential surface and inserted into the first flame flow path portion to separate the first flame flow path portion and the outer circumferential surface of the second guide pipe portion. Non-electric explosion bolt.
The method according to claim 9,
The flame hole includes a plurality of first flame holes located in the first flame flow path portion, and a plurality of second flame holes located in the second flame flow path portion,
The auxiliary flame hole may include a plurality of first auxiliary flame holes positioned to correspond to the plurality of first flame holes, and a plurality of second auxiliary flame holes positioned to correspond to the plurality of second flame holes. Non-electric explosion bolt.
The method according to claim 8,
The first flame guide flow path portion is a straight guide flow path positioned in the longitudinal direction of the first guide pipe portion, and a cone-shaped cone positioned at an end side of the straight guide flow path and gradually expanding in diameter toward the end side of the first guide pipe portion Including an inlet,
The second flame guide flow path portion has a diameter larger than the diameter of the straight guide flow path and has a diameter smaller than the final diameter of the cone inlet, non-electric explosion bolt characterized in that the shape.
The method according to claim 11,
The other end side of the flame guide tube member is connected to the auxiliary ignition weak portion located on the end side of the flame inlet,
The auxiliary ignition weak portion is ignited by the flame introduced into the second flame guide flow path portion, a non-electric explosion bolt, characterized in that to amplify the flame.
A launch tube fixing member mounted and fixed to the launch tube;
A projectile fixing member positioned to protrude on an outer circumferential surface of the projectile located in the launch tube and coupled with the launch tube fixing member;
And a non-electric explosive bolt that penetrates through the launch tube fixing member and is fastened to the projectile fixing member to secure the projectile to the launch tube.
The non-electric explosive bolt is ignited by a flame in the launch tube and separated into at least two bodies to separate the launch tube fixing member and the projectile fixing member,
The non-electric explosion bolt,
Including the bolt body member in which the claim weak portion for explosion is located inside and the thread portion is located on the outer circumferential surface,
On the other end side of the bolt body member, a plurality of flame holes are positioned to allow the flame in the launch tube to flow into the inside, and the flame is exploded by the flame introduced into the flame holes.
The bolt body member,
A bolt portion in which a thread portion is located on the outer circumferential surface;
A rupture portion that extends on one side of the bolt portion and that has an explosive storage space located therein that breaks upon explosion of the captive medicine; And
A projectile characterized in that it comprises a flame inlet, which is located on one side of the rupture portion and is located in a longitudinal direction with a flame movement path connected to the powder storage space and a plurality of flame holes spaced apart in the longitudinal direction. Separation device.
delete delete The method according to claim 13,
A projectile separation device, characterized in that a notched groove for cutting the bolt body member into two parts is located on an outer circumferential surface of the breaking part.
The method according to claim 13,
The projectile separation device, characterized in that the flame inlet has a larger diameter than the fracture.
The method according to claim 13,
A projectile separating device, characterized in that a main ignition medicament for igniting the assertion medicament is located on the other side of the assertion medicament in the gunpowder storage space.
The method according to claim 18,
A projectile separation device, characterized in that a plurality of flame holes are formed to be spaced apart in the longitudinal direction, and a plurality of flame holes are formed to be spaced apart in the longitudinal direction on the outer circumferential surface of the flame inlet.
The method according to claim 18,
A flame guide tube member is located in the gunpowder movement passage of the flame inlet,
The flame guide tube member is a flame guide flow path portion for guiding the flame into the main ignition weak and the flame is introduced therein, and a plurality of auxiliary flame holes connected to the flame guide flow path portion in the longitudinal direction on the outer circumferential surface are located. Projectile separation device characterized by.
The method according to claim 20,
The flame movement passage includes a first flame flow path portion having the same diameter as the gunpowder storage space, and a second flame flow path portion formed with a larger diameter than the first flame flow path portion,
The flame guide pipe member is located in the first flame flow path portion, a first guide pipe portion in which a first flame guide flow path portion is located in a longitudinal direction therein; And
A second guide in which a second flame guide passage part connected to the first flame guide passage part is positioned in the longitudinal direction, and a plurality of auxiliary flame holes connected to the second flame guide passage part are spaced apart in the longitudinal direction on the outer circumferential surface. Projectile separation device comprising a tube.
The method of claim 21,
It characterized in that the protruding portion for pipe support is located on one end side of the second guide tube portion protruding toward the outer circumferential surface and inserted into the first flame flow path portion to separate the first flame flow path portion and the outer circumferential surface of the second guide pipe portion. Projectile separation device.
The method according to claim 22,
The flame hole includes a plurality of first flame holes located in the first flame flow path portion, and a plurality of second flame holes located in the second flame flow path portion,
The auxiliary flame hole may include a plurality of first auxiliary flame holes positioned to correspond to the plurality of first flame holes, and a plurality of second auxiliary flame holes positioned to correspond to the plurality of second flame holes. Projectile separation device.
The method of claim 21,
The first flame guide flow path portion is a straight guide flow path positioned in the longitudinal direction of the first guide pipe portion, and a cone-shaped cone positioned at an end side of the straight guide flow path and gradually expanding in diameter toward the end side of the first guide pipe portion Including an inlet,
The second flame guide flow path portion has a diameter larger than the diameter of the straight guide flow path and has a diameter of a straight path having a diameter smaller than the final diameter of the cone inlet, the projectile separation device.
The method according to claim 24,
The other end side of the flame guide tube member is connected to the auxiliary ignition weak portion located on the end side of the flame inlet,
The auxiliary ignition weak portion is ignited by the flame introduced into the second flame guide flow path portion, a projectile separation device, characterized in that to amplify the flame.
The method according to claim 13,
The launching tube fixing member is mounted on the launching tube by a bolt fastening and can be replaced when the non-electric explosion bolt is damaged by an explosion.
The method according to claim 26,
On the inner circumferential surface of the launch tube, a fixed supporting protrusion is protruded,
The projectile separating device, characterized in that the fixed support protrusion is bolted to the launch tube fixing member and supports an upper surface of the projectile fixing member.

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