KR20040073139A - Firing fin type explosive bolt - Google Patents

Abstract

PURPOSE: A firing pin type explosive bolt is provided to lower a manufacturing price and to simplify an assembling process by allowing separate gunpowder to burst without using connection gunpowder and a connection sleeve. CONSTITUTION: A firing pin type explosive bolt includes a screw forming part(12), a body(11), a body of a bolt(10), an explosive member(20), an igniter(30), an ignition unit(44), and an explosive bolt. The screw forming part has an outer peripheral surface including a screw. The screw forming part(12) is integrated with the body at the end part of the body(11). The body of the bolt(10) has a mounting groove. The igniter(30) generates pressure for ignition. The igniter(30) is mounted in an upper part of the mounting groove. The explosive member includes separate gunpowder.

Description

FIRING FIN TYPE EXPLOSIVE BOLT}

TECHNICAL FIELD The present invention relates to an explosive bolt, and more particularly to an explosive bolt type (Firing Pin type) explosive bolt for detonating the immersion detonator to operate a separate gunpowder.

In general, the bolt is used as a means for joining the two mechanical parts is the most widely used bolts of various types of fastening applications in various parts is not exaggeration.

However, in order to separate the two members joined by the bolt, it is necessary to turn several times several times in the opposite direction from the time of fastening, so it is impossible to instantly separate the two members joined by the bolt.

Therefore, in the related art, an explosive bolt has been developed in order to be able to instantaneously separate two members joined by bolts.

As one of the related arts related to such an explosive bolt, there is one disclosed in the Republic of Korea Patent Publication (Registration No. 1994-191913) invented by Lee Hyo-nam, the inventor of the present invention.

The explosion bolt by Lee Hyo-nam et al., When an electrical signal is applied to the detonator installed inside the bolt body joining the two coupling members through the lead wire, the explosive powder explodes by the detonator action of the detonator. It is configured to separate instantly.

As another conventional technique of the explosion bolt, there is one described in the Republic of Korea Patent Publication No. 10-0294112 invented by Lee Eungjo.

The explosive bolts by this condensation are manufactured by separating the bolt body and the explosion unit separately, so that the detonator and the gunpowder can be taken from the bolt body to prevent safety accidents caused by the separation gunpowder and to facilitate the management. It is configured to be.

As another related art related to an explosion bolt, there is one disclosed in Korean Patent Application No. 2002 Patent Application No. 6291.

The explosion bolt is composed of a bolt body formed with a cylindrical explosion means mounting portion in the longitudinal direction at the head portion, the explosion means detachably or integrally coupled to the inside of the explosion means mounting portion. In addition, a cutting positioning groove is formed on the outer circumferential surface of the bolt body in a position close to the inner bottom surface of the explosion means mounting portion. The explosive means includes a separating powder filled in the inner bottom surface of the exploding means mounting portion, a connecting sleeve installed on the upper side of the separating powder, a connecting powder filled in the connecting sleeve, and an igniter for detonating the connecting powder. It is composed.

When separation of the explosive bolt is required, when an electrical signal is applied to the igniter, the explosive powder is ignited by the operation of the igniter, and the explosive bolt is detonated by the ignition of the explosive powder.

At this time, the shock wave generated during the operation of the explosion bolt is concentrated where the cutting positioning groove of the outer peripheral surface of the explosion bolt is formed to separate the explosion bolt. The explosion bolt is to minimize the amount of powder needed to remove the bolt to minimize the explosion impact and debris generated during the operation of the explosion bolt.

However, in order to reduce the explosion impact of the explosive bolts in the related art, the assembly process is complicated and the price is increased because the connection sleeves filled with the connection powder which operates the separation gun after being detonated in the initiator are installed. There was a problem.

Accordingly, an object of the present invention is to provide a submerged explosive bolt having a simple assembly process and low cost since it is possible to operate a separate powder without using a connecting powder and a connecting sleeve.

1 is a longitudinal sectional view of a sunken explosion bolt according to the present invention;

Figure 2 is a longitudinal sectional view showing the bolt body of the sunken explosion bolt according to the present invention.

Figure 3 is a photograph showing a state before the separation of the explosion bolt according to the present invention,

Figure 4 is a photograph showing a separated state of the explosion bolt according to the present invention.

** Description of symbols for the main parts of the drawing **

10: bolt body 11: the body

12: screw forming portion 15: mounting groove

15a: Ignition device mounting portion 15b: Detonation means insertion portion

15c: Explosion means charging section 16: Cutting positioning groove

20: explosion means 21: separate gunpowder

30: ignition device 31: heat generating unit

32: pressure generating unit 40: sinking detonation means

41: sinking 43: sinking

44: Aerator 44a: Aerator Sleeve

44b: detonation about 45: pressure transfer ring

46: safety sleeve

In order to achieve the object of the present invention, the body portion is formed integrally with the lower end of the body portion and consists of a screw forming portion having a screw portion on its outer circumferential surface. A bolt body having a mounting groove formed in an area reaching the boundary of the screw forming portion; Explosion means filled in the lower end of the mounting groove; A igniter mounted on an upper end of the mounting groove to generate pressure for detonation; A submerged explosion bolt is provided, comprising: a submerged detonation means inserted into the discontinuity of the mounting groove and detonated by hitting the detonator by the pressure generated in the igniter to explode the detonation means. .

The mounting groove is composed of the igniter mounting portion of the upper portion, the detonation means inserting portion of the interruption, the explosion means charging portion of the lower portion, the inner diameter of the igniter mounting portion is the largest, the inner diameter of the explosion means charging portion is the smallest, The inner diameter is formed in its intermediate size.

The explosive means is a separate powder filled in the explosive charge part.

The igniter is composed of a heat generating portion for generating heat by an electrical signal, and a pressure generating portion mounted on the igniter mounting portion to generate pressure by heat generated in the heat generating portion and to apply to the immersion detonation means.

A female screw portion is formed on the inner circumferential surface of the igniter mounting portion, and a male screw portion is formed on the outer circumferential surface of the pressure generating portion of the igniter.

The submerged detonation means is inserted into the detonation means insertion portion between the explosion means and the igniter, the submerged having a submerged main body facing the pressure generating portion of the igniter and a protruding part formed on the lower surface of the submerged main body; It is installed on the upper surface of the explosion means and comprises a detonator hitting and detonating by the needle of the sinking. The initiator consists of an initiator sleeve and an initiator filled in the inside of the initiator sleeve.

A safety sleeve is installed between the sink and the detonator so that the needle and the upper surface of the detonator always maintain a predetermined interval. The safety sleeve includes a cylindrical portion having an inner diameter larger than the needle diameter, an upper surface portion integrally formed at an upper end of the cylindrical portion, and a through hole penetrating through the central portion of the upper surface portion to penetrate the needle portion.

A pressure transfer ring is inserted between the pressure generating portion and the sinking of the igniter. On the outer circumferential surface of the pressure transfer ring and the inner circumferential surface of the igniter mounting portion in which the pressure transfer ring is located, a guide uneven portion is formed to guide the pressure transfer ring to perform non-rotation and linear motion. The guide uneven portion is formed in a splined shape.

Hereinafter, the sunken explosion bolt according to the present invention will be described in detail according to the embodiment shown in the accompanying drawings.

Figure 1 is a longitudinal sectional view of the sunk explosion bolt according to the present invention, Figure 2 is a longitudinal sectional view showing the bolt body of the sunk explosion bolt according to the present invention, Figure 3 shows a state before the separation of the explosion bolt according to the present invention. Photo, Figure 4 is a photograph showing a separated state of the explosion bolt according to the present invention.

The sunk explosion bolt according to the present invention, as shown in Figure 1, the bolt unit 10, the explosion means 20, the igniter (Ignitor) 30, the sunken detonator (Detonator 40) It is composed.

The bolt body 10 is the body portion 11, the screw forming portion 12 is formed extending from the lower end of the body portion 11, the screw portion 13 is formed on the outer peripheral surface, and the body portion 11 ) Is composed of a head portion 14 formed at the upper end.

In the illustrated example, the body portion 11 and the head portion 14 are illustrated as being clearly distinguished, but are not necessarily limited thereto, and the body portion 11 and the head portion 14 have substantially the same cross-sectional shape. Since it may be applied to the form of the following, the body portion 11 and the head portion 14 is collectively referred to as the body portion (11).

Inside the bolt body 10, a mounting groove 15 is formed to be opened at the upper end of the bolt body 10.

The mounting groove 15 is formed at an area whose lower end reaches a boundary portion between the body portion 11 and the screw forming portion 12.

As shown in Figure 2, the mounting groove 15 is composed of a igniter mounting portion (15a) of the upper end, the detonation means inserting portion (15b) of the stop, the explosion means charging portion (15c) of the lower end.

An internal threaded portion 15a 'is formed on the inner circumferential surface of the igniter mounting portion 15a to screw the igniter 30 in a threaded manner.

The inner diameter of the igniter mounting portion 15a is the largest, the inner diameter of the explosion means charging portion 15c is the smallest, and the inner diameter of the detonation means inserting portion 15b is formed in the middle size thereof.

In this way, different diameters of the igniter mounting portion 15a, the detonation means inserting portion 15b, and the explosion means charging portion 15c may facilitate the assembly of the separating means 20 and the submerged detonation means 40 and the like. To make it work.

The explosion means charging portion 15c is formed such that the lower end thereof is located inside the boundary portion between the body portion 11 and the screw forming portion 12.

On the outer circumferential surface between the body portion 11 and the screw forming portion 12, a cutting positioning groove 16 is formed to predetermine the cutting position of the bolt body 10 when the explosion means 20 explodes.

The explosive means 20 is composed of a separate explosive charge 21 filled in the explosive means charging section (15c).

The igniter 30 is composed of a heat generating portion 31 for generating a pressure in accordance with an electrical signal and a pressure generating portion 32 for generating a pressure by the heat generated from the heat generating portion (31).

The outer circumferential surface of the pressure generating portion 32 is formed with a male screw portion 32 'which is fastened to the female screw portion 15a' formed on the inner circumferential surface of the igniter mounting portion 15a.

The igniter 30 has a heating wire (nichrome wire) 33 is built into the heat generating portion 31, and the pressure generating portion 32 is a detonating agent (34) detonated by the heat generated by the heating line (33) And a conventional one filled with the explosive medicine 35 exploded by the detonation of the initiator 34 is used.

Here, the configuration of the igniter itself, which is composed of the heating wire 33, the detonating agent 34, the anti-pilling agent 35 and the like, is one of the igniters already widely used and does not have a direct relationship with the main part of the present invention. In order to be suitable for coupling the machine 30 to the bolt ball body 10, a male screw part 32 'is formed on the outer circumferential surface of the pressure generating part 32.

Reference numeral 36 denotes a contact pin for applying power, 37 an RF filter, 38 a glass bead, and 39 a protective film.

The submerged detonator means 40 is inserted and installed in the detonator means inserting portion (15b) formed between the igniter 30 and the explosion means 20, the top surface of the igniter (30) A submerged body 41 having a submerged body 42 facing the lower end, and a needle 43 protruding from and formed at the lower end surface of the submerged body 42; And a detonator 44 positioned between the needle 43 of the sinking 41 and the separation gunpowder 21 of the explosion means 20.

The initiator 44 is composed of an initiator sleeve 44a and an initiator medicine 44b filled in the inside of the initiator sleeve 44a.

The lower end surface of the igniter 30 and the upper end surface of the sinking 41 may be configured to be in direct contact, but as shown in the example, the igniter is placed between the lower end surface of the igniter 30 and the upper surface of the sinking 41. It is preferable to provide a pressure transfer ring 45 for transmitting the pressure generated at 30 to the sink 41.

Guide concave and convex portions 45 'and 15a' for allowing the linear movement of the pressure transfer ring 45 without rotating the pressure transfer ring 45 on the outer circumferential surface of the pressure transfer ring 45 and the lower inner circumferential surface of the igniter mounting portion 15a. Is formed.

These guide uneven parts 45 ', 15a "are formed in the form of a spline, for example.

In addition, the submerged 41 may be disposed in a state where the lower end of the needle 43 is spaced apart from the upper surface of the detonator 44, but is inserted between the lower surface of the submerged body 42 and the upper surface of the detonator 44 as shown in the example. It is desirable to install a safety sleeve 46 to be.

The safety sleeve 46 is composed of a cylindrical portion 46a having an inner diameter larger than the diameter of the needle portion 43 and an upper surface portion 46b integrally formed at an upper end of the cylindrical portion 46a. A through hole 46c is formed in the central portion of the 46b to penetrate the needle 43 of the sink 41.

The bolt body 10 is made of stainless steel such as 17-4PH (SUS 630), and the material of the sink 41 is made of stainless steel such as SUS 304.

The pressure transfer ring 45 is formed of stainless steel such as 17-4PH, and the safety sleeve 46 is formed of acrylic so that the pressure of the igniter 30 is transmitted through the pressure transfer ring 45. It is designed to be destroyed by pressure.

The detonator 44 is used that can detonate by hitting the needle 43 of the sinking 41 even without a separate primer. For example, a immersion having a weight of 1/2 oz is used to the extent that it can be detonated by the impact of a natural fall at a height of 2 inches or more.

Reference numeral 47 in the drawings is an O-ring.

In the sunk explosion bolt according to the present invention configured as described above, as shown in Figures 1 and 3, the upper surface of the sinking 41 is in contact with the lower surface of the igniter 30 through the pressure transfer ring (45). And a pair of lower ends of the needles 43 of the sinking 41 are manufactured to be spaced apart from the upper surface of the detonator 44b of the detonator 44 to connect the threaded portion 13 of the bolt body 10. The connecting member (not shown) will be connected.

At this time, since the safety sleeve 46 maintains a constant distance between the needle 43 of the sinking 41 and the detonating agent 44b until the explosion bolt is operated, the detonating agent 44b is arbitrarily selected by the submerging 41. There is no detonation.

When an electrical signal is applied to the igniter 30 in this state, pressure is generated in the igniter 30, and the pressure is transmitted to the upper end surface of the sinking 41 through the pressure transfer ring 45, which is the pressure. The sinking 41 advances rapidly by this.

At this time, the safety sleeve 46, which is maintained between the upper surface of the detonating agent 44b and the tip of the needle 43 of the sink 41 at a predetermined interval, is destroyed by the pressure transmitted through the pressure transfer ring 45 and soaked. (41) makes the state to advance rapidly.

The needle 43 of the sinking 41 strikes the detonation agent 44b of the detonator 40, and thus detonation agent 44b is detonated and separation of the explosion means 20 by detonation of the detonation agent 44b. Explosives 21 will explode.

At this time, the pressure transfer ring 45 is guided only in a linear direction by the guide concave and convex portions 45 'and 15a "formed on the outer circumferential surface and the inner circumferential surface of the igniter mounting portion 15a, so that the pressure transfer action can be made smoothly and accurately. do.

In addition, the safety sleeve 46, which is kept constant between the needle 43 and the detonation agent 44b of the sink 41, is a pressure when the sink 41 starts to move forward by the pressure generated in the igniter 30. It deforms or breaks by pressure, and the needle part 43 of the sinking 41 is in the state which can strike the detonation agent 44b.

Cutting position of the bolt body 10 formed between the body portion 11 and the screw forming portion 12 as shown in Figure 4 due to the impact of the explosive powder 21 of the explosion means 20 exploded The pair of connecting members which are cut in the grooves 16 and connected by the bolt body 10 are momentarily separated.

According to the test, the submerged explosive bolt according to the present invention was found to have the same separation time when operated at room temperature, low temperature or high temperature.

In addition, in the submerged explosive bolt of the present invention, the pressure of the igniter 30 is not directly applied to the detonator 40, but the adsorbed portion 41 of the submerged 41 is rapidly detonated by rapidly advancing the submerged 41. ), The operation reliability is very high.

That is, when the pressure of the ignition device 30 is applied directly to the detonation agent 44b of the detonator 40, the detonation is not performed, and thus the separation gun 21 may not explode. In the detonation (41) is to strike the detonation agent (44b), so that the detonation of the detonation agent (44b) and the explosion of the separation gun (21) will be made sure.

According to the experiment, the pressure generated in the igniter 30 was found to be normal operation of the explosion bolt at 300psi or more.

In addition, in the case of the explosive bolt using a conventional explosive powder, a lot of detonator of about 100 mg was needed, but the submerged explosive bolt of the present invention can be seen that the operation of the explosive bolt is smoothly performed while using a small amount of detonator of about 20 mg. there was.

In addition, in the explosive bolt using a conventional gunpowder, a female thread part is formed on the inner circumferential surface of the middle part of the explosion means mounting groove, and a male thread part is formed on the connecting sleeve filled with the connection gun powder to install the connecting gun powder by fastening these female thread parts and the male thread part. Since the assembly of the explosive bolt is cumbersome and increases the manufacturing cost, the submerged explosive bolt of the present invention is easy to assemble the explosive bolt, because the use of the sedimentation without using the gunpowder and the connecting sleeve is easy, It will be possible to save.

As described above, the sunken explosion bolt of the present invention can increase the reliability of operation of the explosion bolt without using an electric bomber, a connecting powder or a connecting sleeve, so that the assembly is simple and the manufacturing cost can be reduced. It is.

Claims (12)

It consists of a body part and a thread-forming part which is integrally formed at the bottom of the body part and has a threaded part on its outer circumferential surface.It is formed inside the body part and is opened in the upper part of the body part, and is mounted in an area from the lower part to the boundary part of the body part and the threaded part. A groove formed in the bolt body; Explosion means filled in the lower end of the mounting groove; A igniter mounted on an upper end of the mounting groove to generate pressure for detonation; A submerged detonation means inserted into the discontinuity of the mounting groove to detonate by detonating the detonation medicine by the pressure generated in the igniter to explode the detonation means; The sunken explosion bolt, characterized in that configured to include. According to claim 1, wherein the mounting groove is composed of the igniter mounting portion of the upper end, the detonation means inserting portion of the interruption, the explosion means charging portion of the lower portion, the inner diameter of the igniter mounting portion is the largest, the inner diameter of the explosion means charging portion is the smallest The inner diameter of the explosion means insertion portion is a submerged explosion bolt, characterized in that formed in the medium size. The sunken explosion bolt according to claim 1 or 2, wherein the explosive means is a separate explosive charge filled in the explosive charge part. According to claim 2, wherein the igniter is composed of a heat generating unit for generating heat by an electrical signal, and a pressure generating unit mounted on the igniter mounting portion for transmitting the pressure generated in the heat generating portion to the sinking detonation means Sunken explosion bolts. 5. The sunken explosion bolt according to claim 4, wherein a female screw portion is formed on an inner circumferential surface of the igniter mounting portion, and a male screw portion is formed on an outer circumferential surface of the pressure generating portion of the igniter. 3. The immersion main body according to claim 1 or 2, wherein the immersion detonation means is inserted into the detonation means insertion section between the explosion means and the igniter, and the immersion main body facing the pressure generating part of the igniter and the submerged main body. A submerged explosion bolt, characterized in that it comprises a immersion having a needle formed protruding on the lower surface, and a detonator which is installed on the upper surface of the explosion means and detonated by the immersion of the immersion. 7. The sunken explosion bolt as claimed in claim 6, wherein the initiator consists of an initiator sleeve and an initiator filled in the inside of the initiator sleeve. The immersion explosion bolt according to claim 6, wherein a safety sleeve is installed between the sink and the detonator so that the needle and the upper surface of the detonator maintain a constant interval at all times. The safety sleeve according to claim 8, wherein the safety sleeve comprises a cylindrical portion having an inner diameter larger than the needle diameter, an upper surface portion integrally formed at an upper end of the cylindrical portion, and a through hole drilled through a central portion of the upper surface portion to penetrate the needle portion. Sunken explosion bolt characterized in that. 7. The sunken explosion bolt according to claim 6, wherein a pressure transfer ring is inserted between the pressure generating portion and the sunk of the igniter. 11. The sunken explosion as set forth in claim 10, wherein the outer circumferential surface of the pressure transfer ring and the inner circumferential surface of the igniter mounting portion in which the pressure transfer ring is located are formed with guide concave-convex parts for guiding the non-rotation and linear movement of the pressure transfer ring. volt. 12. The sunken explosion bolt according to claim 11, wherein the guide uneven portion is formed in a splined shape.