JP3875573B2 - Cord explosive, cord explosive connection device and cord explosive device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention includes a cord-shaped explosive formed in a long cord-like body (rope), a cord-shaped explosive connecting device that connects the cord-shaped explosive, and a cord-shaped explosive connecting device that connects the cord-shaped explosive. The cord explosive device is
[0002]
[Prior art]
Conventionally, explosives mainly used for treating landmines in mine fields include Comp. There is a cord explosive using C-4 explosive (NDS standard: No. 4 explosive; hereinafter referred to as C-4 explosive).
This cord explosive is manufactured as follows, for example.
First, the C-4 explosive is formed into a cylindrical shape having a length of about 10 to 20 cm and a diameter of about 25 to 30 mm, packed in a polyethylene bag with a bottom, bent at one end of the polyethylene bag, and taped at the four corners. As a result, a single medicine package (explosive in a polyethylene bag) is obtained.
[0003]
Next, a single long rope-like cord-shaped explosive is prepared by packing a large number of this single-drug package into a cylindrical Tetron (registered trademark) sleeve (tube) having a length of about 10 to 15 m. .
This C-4 explosive has RDX (90%), plasticizer (10%) “polyisobutylene, di (2-methylhexyl) separate, lubricating oil” and odorant (external discount 1%).
[0004]
Cord explosives using C-4 explosives must be folded and transported and installed in a small amount before the development of landmine treatment, and must have the property of being freely folded.
For this reason, as described above, the polyethylene bag is filled with the C-4 explosive, and the explosive in the polyethylene bag is further filled in one tube to maintain flexibility.
[0005]
Here, flexibility is expressed by utilizing the property that the cord-shaped explosive bends at the boundary with each single-pack of polyethylene bags.
Although this C-4 explosive has plasticity, it does not have physical strength, and if the tensile force is applied to the molded explosive even a little, it will be cut off and the shape cannot be maintained by the explosive itself. It is packed in a polyethylene bag so that it can withstand post-processing work.
In addition, when many single medicine packs packed with C-4 explosives in polyethylene bags (about 100 to 150 mm in length) are packed into Tetron (registered trademark) sleeves (outer skins), each single medicine pack is connected to the connector manually. The diameter of the cord explosive is increased by crushing in the direction of
[0006]
As a result, when the explosive explosive is spread on the minefield, the outer expanse of the explosive explosive expands, and each single drug capsule of the explosive explosive is pressed against the expanse by the elongation of the expanse and the diameter of the explosive explosive is reduced. .
As a result, each single medicine package extends as much as it is pressed to prevent the formation of a gap between the cord-shaped explosive and the explosive in the connecting portion.
[0007]
In addition, as shown in FIG. 11, the connecting tool for connecting the cord explosive as described above has a hollow portion 2 in which the C-4 explosive 1 can be loaded and a tubular tube 3 penetrating therethrough. The joint A is formed, and the joint B is formed by a cylindrical tubular body 5 having a hollow portion 4 in which the C-4 explosive 1 can be similarly loaded.
[0008]
In addition, the joint A and the joint B include joint connecting portions 6 and 7 that are fitted and fixed to each other, and cord explosive connecting portions 8 and 9 that are connected to the cord explosive 10. And the front-end | tip of the joint connection part 6 of the joint A is formed in the T-shaped convex part shape, and the front-end | tip of the joint connection part 7 of the joint B is formed in the T-shaped recessed part shape. This is because the joint connecting portion 6 having a T-shaped convex shape of the joint A is inserted into the joint connecting portion 7 having a T-shaped concave shape of the joint B.
[0009]
Further, on the trunk portions 3a and 5a of both joints A and B, a protrusion 11 is formed on the circumference of the trunk portion at a portion near the center of the trunk portions 3a and 5a.
When the C-4 explosive 1 is loaded into the joint A and the joint B, the joint connecting portions 6 and 7 of both joints A and B are closed with the aluminum thin plate 12, and the explosive explosive connecting portions 8 and 9 are connected. Load it. And after loading, the cable-shaped explosive connection 8, 9 side of both joints A, B is closed with aluminum thin plates 13, 14.
[0010]
Moreover, it arrange | positions so that the front end surface part of each cord-like explosive 10 may face | match the cord-like explosive connection part 8 and 9 of both these joints A and B. FIG.
Then, a Tetron (registered trademark) sleeve (hereinafter referred to as a sleeve) 10a at the tip of each cord-shaped explosive 10 is pulled out so as to cover the trunk portions 3a and 5a of both joints A and B. Here, in the projection part 11 formed in the trunk | drum 3a, 5a, the sleeve 10a and the trunk | drum 3a, 5a are clamped and fixed using the punch band 15. FIG. Further, the sleeve and the trunk portion are similarly fastened and fixed at the positions of the trunk portions 3a and 5a close to the cord-shaped explosive 10 using a punch band.
[0011]
[Problems to be solved by the invention]
However, as described above, the C-4 explosive cannot obtain a long shape with the explosive itself. Therefore, the C-4 explosive itself is packed into a single medicine package packed in a polyethylene bag and then packed into a tube for making the length long. To withstand such work.
Therefore, it was necessary to manufacture many single medicine packages.
In the case of a single-drug package with a small diameter, it is necessary to pack the explosive in a polyethylene bag, fold one end of the bag and tape the four corners with tape, and it is extremely complicated. There is a problem that the number of processing steps does not change even though the number is reduced, resulting in an increase in cost.
[0012]
In addition, for example, when making a long cord-shaped explosive of 15 m or more, a plurality of single-powder bags with polyethylene bags are packed into a tube to form a single cord-shaped explosive with a length of 5 m, and a plurality of cord-shaped explosives are prepared. These are connected by a connector, but at that time, each single medicine package is crushed in the direction of the connection tool by hand, and the diameter of the cord-shaped explosive is increased. There are problems that the number of processes and the labor cost are greatly increased because the operation of inserting and the operation of compressing the single drug package thickly while inserting is performed manually.
[0013]
Also, when explosive explosives are expanded to a length of 100m in order to explode buried explosives such as landmines in landmine fields, they are placed inside a connector that connects the explosive explosives with the expanded force. There may be a gap between the explosive and the cord-shaped explosive connected to the connector.
This is thought to be due to the difference in elongation between the explosive in a single drug package and the tube that is the outer skin.
[0014]
If this gap is large, there is a risk of detonation interruption not transmitting from the explosive disposed inside the connecting portion from the explosive explosive or from the explosive disposed inside the connecting portion to the explosive explosive.
Here, stretching means stretching the cord explosive straight. This expansion work was done by connecting one end of a cord-shaped explosive that was folded by a soldier to the end of a small rocket when using a cord-shaped explosive, launching (projecting) the rocket forward, and folding the rocket while flying in the air. This is done by drawing out the explosives and stretching them over a minefield with a length of 20-100 m or more.
[0015]
The present invention has been made to solve the above-mentioned problems, and an object thereof is to provide a long (for example, 5 m or more) cord-like explosive having flexibility. Another object of the present invention is to provide a long (for example, 5 m or more) cord-like explosive having flexibility that can eliminate poor transmission.
Another object of the present invention is to provide a cord-like explosive connecting device capable of connecting a long (for example, 5 m or more) cord-like explosive having flexibility.
[0016]
Still another object of the present invention is to provide a cord-like explosive device in which a long (for example, 5 m or more) cord-like explosive having flexibility is connected by a cord-like explosive connecting device. .
[0017]
[Means for Solving the Problems]
  The invention according to claim 1 is provided at a plastic explosive formed by extruding into a long cord-like body, a protective member covering the outside of the plastic explosive over the entire length, and at least one side end of the plastic explosive. Consists of with connection toolThe connector is composed of a cylindrical body that covers the end of the plastic explosive covered with the protective member, and an explosive that has an explosive speed than the plastic explosive loaded in the cylindrical body.It is characterized by that.
  Here, as the plastic explosive, for example, a mixture of a solidified explosive and a binder is used.
  As the solidified explosive, RDX (trimethylenetrinitroamine), PETN (pen slit), HMX (cyclotetramethylenetetranitramine) and the like can be used.
[0018]
As the binder, for example, a reaction curing type silicone resin can be mixed, but in order to control the softness of the silicone resin, a plasticizer such as DOA (dioctyl adipate) or DOS “di (2-methylhexyl) separate” is used. Can be added.
In addition, an additive such as a pigment (graphite) can be added in order to visually check the mixing condition of the curing agent.
[0019]
  The protective member can be layered as necessary to cover the cord explosive and increase the strength of the cord explosive against the external environment.
  The invention according to claim 12A plastic explosive formed by extruding into a long cord-like body, a protective member covering the entire length of the plastic explosive, and a liner portion in which a liner for generating a jet is disposed, the plastic explosive The liner portion is provided with an explosive having an explosive speed than the plastic explosive.It is characterized by that.
[0020]
  Here, the explosive having an explosive speed than the plastic explosive is used to effectively transmit the plastic explosive. For example, a P-4 explosive mixed with 91% pen slit (PETN) and 9% binder is used. An explosive with a higher explosion speed than a plastic explosive can be selected.
  The invention according to claim 33. The cable-shaped explosive according to claim 2, wherein the connection tool includes a cylindrical body that covers an end portion of the plastic explosive covered with the protective member, and the liner portion that is disposed in the cylindrical body. Be doneIt is characterized by that.
[0021]
The liner portion can have a cross-sectional shape inside the cord-shaped explosive having a semicircular shape, a semi-elliptical shape, a trapezoidal shape, or the like, and a liner that matches the shape can be disposed.
Here, if the liner is, for example, a circular cord-shaped explosive, a thin conical copper plate or the like is pasted, or a mixture of metal powder and resin (binder) is formed into a conical shape and pasted. Can do.
[0022]
  The liner is preferably a thin copper plate attached to the inner surface of the end of the cord explosive in accordance with the diameter and shape of the cord explosive.
  The invention according to claim 4 is claimed in claim1 or claimIn the cord explosive described in 3,The end of the plastic explosive covered with the protective member and the cylindrical body are fixed by a fixing member.It is characterized by that.
[0023]
  The invention according to claim 5 is claimed in claimAny one of claims 1 to 3In the described cord explosive,The plastic explosive is a plastic explosiveIt is characterized by that.
  The invention according to claim 6 is the claimAny one of claims 1 to 3In the described cord explosive,The plastic explosive is a mixture of a solidified explosive and a binder.It is characterized by that.
[0024]
  The invention according to claim 7 is the claim6In the described cord explosive,The binder is used as an adhesive when connecting one end surfaces of the plastic explosives after curing to a long cord-like body after reaction curing.It is characterized by that.
  The invention according to claim 8 is the claim7In the cord explosive described, the binder is:Silicone resinIt is characterized by that.
[0025]
  After the binder is mixed with the explosive base to make a long cord-like body, this same binder is used to bond the end faces of other cord-like explosives manufactured in the same manner as the end face of the cord-like explosive Use as
  The invention according to claim 9 is the claimAny one of claims 1 to 3In the described cord explosive,The protective member is a laminated tubeIt is characterized by that.
[0026]
  The invention according to claim 10 is the claim 1 or claim.2In the cord-shaped explosive described, the protective member isA shrinkable tube that shrinks by heat or lightIt is characterized by that.
  The invention according to claim 11 is the claim2In the described cord explosive,The liner is made of at least one material selected from copper, aluminum, tungsten, titanium or alloys thereof, aluminum oxide, boron carbide, silicon carbide, and graphite.It is characterized by that.
[0027]
The shrinkable tube covers the outer circumference of the cord explosive over the entire length.
As the shrinkable tube, a tube having a characteristic that the diameter of the tube is reduced by external factors such as high-temperature heat (for example, heating, humidification, drying, etc.), a chemical reaction, or a photoreaction can be used.
For example, as a tube by heating, there are tubes made of materials such as flame retardant hard polyvinyl chloride, soft polyvinyl chloride, polyolefin, polyethylene terephthalate, polyvinyl chloride, and preferably after shrinkage A heat-shrinkable tube having elasticity is good, and among them, a polyolefin-based heat-shrinkable tube is preferable.
[0028]
  The invention according to claim 12 is the claim1Listed cord explosivesIn the cable-shaped explosive connecting device for transmitting the cable-shaped explosive, the tubular tube body penetrating from one side to the other side and having the explosive inside thereof, A pair of joints having a joint connecting portion provided on one side of the tubular body, and a liner portion formed by arranging a liner for generating a jet, and an explosion transmitting portion provided on the other side of the tubular body And the pair of joint bodies are coupled and separated via the joint connecting portion.It is characterized by that.
  The invention according to claim 13 is:A plastic explosive formed by extruding into a long cord-like body, a protective member covering the entire length of the plastic explosive, and a liner portion in which a liner for generating a jet is disposed, the plastic explosive In the cable-shaped explosive connection device for connecting a cable-shaped explosive composed of at least one connection end of the cable-shaped explosive via the connection tool and transmitting the cable-shaped explosive, from one side Explosive velocity from a tubular tube body penetrating to the other side and having an explosive inside thereof, a joint connecting portion provided on one side of this tube body, a liner portion provided with a liner for generating a jet, or the plastic explosive And a pair of joint bodies provided with an explosive portion provided on the other side of the pipe body, the pair of joint bodies being interposed via the joint connecting portion. Combined and separated To.
[0029]
  The invention according to claim 14 is claimed in claim2The cord-shaped explosive described above and the connection toolWhenIn the cable-shaped explosive connection device for transmitting the cable-shaped explosive, the tubular tube penetrating from one side to the other side and having the explosive therein, and one side of the tube Liner part with a joint connecting part provided in and a liner that generates a jetOr a filling part loaded with an explosive with an explosion speed higher than the plastic explosiveAnd a pair of joint bodies provided on the other side of the tube body, and the pair of joint bodies are coupled and separated via the joint connecting portion. And
[0030]
  The invention according to claim 15 is the claimAny one of claims 12 to 14Listed cord explosivesIn the connecting device, the pair of joint bodies includes a male joint in which the joint connecting portion provided at the tip portion is formed in a convex shape, and a female joint in which the joint connecting portion provided in the tip portion is formed in a concave shape. And a fixing portion that engages and fixes both joint connecting portions provided at the tip portions of both joints.It is characterized by that.
[0031]
  The invention according to claim 16 is claimed in claim15In the cord-shaped explosive connection device described above, the fixing portion is provided with a stopper fixing hole for locking with the female joint on the male joint side, and is engaged with the stopper fixing hole on the female joint side. It is characterized by comprising a stopper for stopping.
  The invention according to claim 17 is the claim12 orClaimAny one of 14In the cord explosive connection device described,The explosive portion is formed in a tubular cord-shaped explosive introduction pipe coupled to the other side of the tubular body.It is characterized by that.
[0032]
  The invention according to claim 18 is claimed in claim17In the cord explosive connection device described,The cord-like explosive introduction tube is a cylindrical single tube having an explosive loading cavity and a cord-like explosive introduction cavity inside, and a connecting portion connected to the other side of the tubular body.It is characterized by that.
  The invention according to claim 19 is the claimThe cord explosive according to claim 1 is connected via the cord explosive connecting device according to claim 12.It is characterized by that.
[0033]
  The invention according to claim 20 providesA plastic explosive formed by extruding into a long cord-like body, a protective member covering the entire length of the plastic explosive, and a liner portion in which a liner for generating a jet is disposed, the plastic explosive A cord-shaped explosive composed of a connecting tool provided on at least one side end of the cord is connected via the cord-shaped explosive connecting device according to claim 13.It is characterized by that.
  The invention according to claim 21 is the claimThe cord explosive according to claim 2 is connected via the cord explosive connecting device according to claim 14.It is characterized by that.
  The invention according to claim 22 is the claim20 or 21Listed cord explosivesIn the deviceThe explosive portion and the cord explosive are opposed to each other via a liner portion formed on the explosive portion and the explosive explosive.
[0034]
  The invention according to claim 23 is the claim20 or 21In the cord explosive device described above, the explosive portion and the explosive portion are opposed to each other via a liner portion formed in either the explosive portion or the explosive explosive.
  The invention according to claim 24 is the claim20 or 21In the cord explosive device described above, the liner portion provided in the connection tool of the cord explosive is provided with a liner so as to generate a jet in the explosion traveling direction.
[0035]
  The invention according to claim 25 is the claim20 or 21In the cord explosive device described above, the liner portion provided in the explosive portion of the cord explosive connection device is provided with a liner so as to generate a jet in the explosion traveling direction. To do.
[0036]
(Function)
The case where the long cord-like explosive device which connected the cord-like explosive which concerns on this invention with the cord-like explosive connection apparatus suitably is extended in a minefield is demonstrated.
The cord explosive device is accommodated in a folded state.
During use, soldiers tie a small rocket to one end of the cord explosive device. When a small rocket is launched, the folded cord explosive device is pulled out and deployed on the minefield. Thereafter, when detonation is performed with an explosive device or the like disposed at one end of the cord explosive device, the explosive in the cord explosive explodes. This detonation will spread to other connected explosives.
[0037]
At that time, when the detonation reaches the end of the cord explosive, the liner (molded glaze) of the liner disposed at the end is compressed by the high pressure and high heat generated by the detonation, and then jumps out forward. .
This jet jumps into the joint connected to the cable explosive on one side, detonates and detonates the explosive in the joint, and is transmitted to the cable explosive on the other side connected to the joint.
[0038]
In addition, when a folded cord explosive device is pulled out and extended, even if a gap (for example, 20 mm) is generated at the boundary between each joint portion and the cord explosive, the liner portion maintains the explosive property and continues to transmit. Explode.
Normally, when two cord-like explosives of about 10 m are connected via a joint portion, when one cord-like explosive is detonated by an initiation device or the like, the explosion rate is 6,500 to 8,000 m / sec.
[0039]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described.
(First embodiment)
1 to 9 show a cord-shaped explosive device according to a first embodiment of the present invention.
The cord explosive device 20 according to the present embodiment includes, for example, two cord explosives 30 and 30 formed to have a diameter of 16 mm and a length of 10 m to 30 m, which are connected by the cord explosive connecting device 40 to 60 m and 120 m. And the length is as needed.
[0040]
First, the cord explosive 30 will be described.
The cord-shaped explosive 30 includes a plastic explosive 31 formed by extruding a mixture of a solidified explosive and a binder into a long cord-shaped body, and a protective member 32 such as a polyethylene bag covering the outside of the plastic explosive 31 over the entire length. And a liner 33 having a liner 35 for generating a jet, and a connector 33 provided at one end of the plastic explosive 31.
[0041]
The plastic explosive 31 is manufactured as follows, for example.
Weigh out 70% to 85% of RDX with relatively fine particles as a solid compound explosive material as the main component, and weigh and mix 15% to 30% of binder (silicone resin, etc.) to obtain a plastic explosive (here, plastic explosive) ) Make 31.
Here, the reason for using RDX with relatively fine particles is that RDX is easy to manufacture, and that it is highly safe from the viewpoint of handling and sensitivity of explosives mixed with binder (silicone resin). .
[0042]
The silicone resin used in the binder is extruded from a molding machine that extrudes into a plastic (polyethylene) tube while maintaining a certain amount (for example, 70%) even if it is mixed with solid RDX, HMX, etc. The one having a low viscosity was selected.
As this silicon resin, Shin-Etsu silicon KE12, Toshiba TSE350, Toray SH555, etc. are preferable. However, in the present embodiment, not only these silicon resins but also a solidified explosive substance (for example, RDX, Even if it mixes with HMX), it may be a silicon resin having physical properties having plasticity that can be easily extruded.
[0043]
Next, a method for producing a rope-like (corrugated) cord-like explosive 30 from the plastic explosive 31 will be described.
First, about 2 kg of a plastic explosive is accommodated in the chamber of the molding machine and extruded from the nozzle portion by an extrusion tool.
The nozzle portion holds a polyethylene bag with a bottom having a predetermined length (protective member 32), and the explosive is pushed into the polyethylene bag while being pushed out of the nozzle at the time of the extrusion molding operation.
[0044]
Then, when the part containing the explosive in the polyethylene bag is detached from the nozzle part and extends out of the nozzle, a long explosive with a diameter of 20 mm and a length of 10 m is formed.
When this is left at room temperature, it becomes a cord-shaped explosive that reacts and cures over time and has elasticity.
Moreover, the extruded 10-m cord explosive can be joined only by this cord-shaped explosive, and it can be set as a 20-m cord explosive.
[0045]
First, two 10-m cord-shaped explosives are prepared, and one end part of the two cord-shaped explosives to be joined is cut obliquely with a blade or the like to form respective joint surfaces.
Then, the same silicon resin liquid as that used as the binder to be mixed with the solidified explosive substance is applied to the joint surfaces cut diagonally of each cord-like explosive to match each joint.
[0046]
Further, the joint surfaces of these cord explosives are temporarily fixed with a gum tape or the like so that the joint surfaces are not separated.
These applied silicon resins penetrate into the cured silicone resin of the cord explosive itself and are cured by reaction, and the explosives are joined together by an adhesive action.
Next, when the cured connection is completed, the temporary fixing is removed, and a portion of about 3 to 4 cm from the joint surface is wound on the polyethylene bag (protective member) with an elastic tape or the like to reinforce the joint surface. .
[0047]
As a result, a cable-shaped exploration with a total length of 20 m is completed.
Here, the composition example of a plastic explosive is shown below.
“Composition Example 1”
RDX 75% and binder (silicon resin) 25% are mixed.
“Composition Example 2”
70% RDX and 30% binder (silicon resin) are mixed.
[0048]
“Composition Example 3”
70% PETN and 30% binder (silicon resin) are mixed.
Next, the connection tool 33 attached to one end portion of the plastic explosive 31 covered with the protective member 32 will be described.
As shown in FIG. 7, the connection tool 33 is formed by a liner storage tool 36 formed of a bottomed cylindrical body with a hole.
[0049]
The liner portion 34 is formed by disposing the liner 35 so that a jet is generated toward the hole 36 a at the bottom of the liner storage tool 36.
The liner portion 34 can have a cross-sectional shape inside the cord-shaped explosive having a semicircular shape, a semi-elliptical shape, a trapezoidal shape, and the like, and a liner 35 can be arranged in accordance with the shape.
[0050]
Here, the liner 35 preferably has a thin copper plate attached to the inner surface of the end of the cord explosive according to the diameter and shape of the cord explosive. For example, the cross-sectional shape inside the cord explosive is circular. If present, a thin copper plate or the like having a conical shape can be attached, or a mixture of metal powder and resin (binder) can be formed into a conical shape and attached.
[0051]
The liner 35 is formed of at least one material selected from metallic materials such as copper, aluminum, tungsten, titanium, and alloys thereof, or nonmetallic materials such as aluminum oxide, boron carbide, silicon carbide, and graphite. Has been.
The liner angle used for the armor-piercing shell is about 42 ° so as to generate an acute angle (linear) jet in order to penetrate the armored vehicle.
[0052]
On the other hand, the liner angle used in the present embodiment is set to about 90 ° so as to increase the area corresponding to the explosive on the side where a plane jet is generated and transmitted to improve the explosive property.
As shown in FIG. 7, on the back side of the liner 35, an explosive (P-4 explosive) 37 having an explosive speed than the plastic explosive 31 is disposed as an initiator for the liner 35. The P-4 explosive is an explosive in which 91% pen slit (PETN) and 9% binder are mixed. PETN has a sharp sensitivity and explodes with a small impact.
[0053]
  As described above, the cord-shaped explosive 20 provided with the liner portion 35 on one end side can be obtained.2Or claims11Corresponding).
  Next, a cord-shaped explosive connection device 20 for connecting the cord-shaped explosive 30 thus obtained will be described with reference to FIGS. 1 to 3.
  The cable-shaped explosive connection device 20 includes tubular tubes 41a and 41b penetrating from one side to the other and having explosives therein, and joint connecting portions 42a provided on one side of the tubes 41a and 41b. 42b and a pair of joint bodies 40A and 40B provided with explosion transmission parts 43a and 43b provided on the other side of the pipe bodies 41a and 41b.
[0054]
The pair of joint bodies 40A and 40B are coupled and separated through joint connecting portions 42a and 42b.
As shown in FIG. 2, the male joint 40A is formed by processing an aluminum cylindrical tube body 41a having a hollow portion (explosive charge loading hole) 45 that is open on one side and the other side and can be filled with an explosive charge 44 inside. It is made by doing.
[0055]
A joint connecting portion 42a is formed at one end portion. The joint connecting portion 42a is formed with a protruding insertion portion 47 that forms a notch step portion 46 that can be inserted into the joint connecting portion 42b of the female joint 40B.
A screw portion 48 is formed on a part of the outer periphery of the trunk portion 40A1 so as to be screwed to the cord-shaped explosive introduction pipe 65 at the other end portion.
[0056]
A flange portion 49 and two stopper fixing holes 50 formed in the flange portion 49 are formed in the vicinity of the insertion portion 47 on the outer periphery of the body portion 40A1. As will be described later, the flange portion 49 and the stopper fixing hole 50 are inserted into the insertion portion 57 of the joint connection portion 42b of the female joint 40B after the insertion portion 47 of the male joint 40B is inserted into the stopper 61 of the joint connection portion 42b. It becomes a stop part which latches.
[0057]
Convex portions 51 are formed at two locations near the center on the outer periphery of the body portion 40A1. As will be described later, this is a fixing portion for fixing the cord-shaped explosive 30 and the cord-shaped explosive connecting devices 40A, 40B from above the outer skin (sleeve) with a wire or the like.
The hollow portion 45 is filled with an explosive charge 44, and an explosive charge portion 44A and an explosive charge portion 44B are formed at both ends.
[0058]
In the present embodiment, the hollow portion 45 is smaller than the inner diameters of the explosive charge portion 44A and the explosive charge agent 44B in order to ensure the aluminum strength that is the joint pipe body by limiting the outer diameter size (φ16 mm) of the cord-shaped explosive 30. It is formed with an inner diameter. In addition, the explosive charge portion 44A and the explosive charge portion 44B increase the pressure receiving area that receives the impact (detonation) from the hollow portion 44 so that the explosive charge 44 is likely to explode.
[0059]
When the outer diameter of the cord-shaped explosive 30 is about φ28 mm, the inner diameter of the hollow portion 45 may be the same as the inner diameter of the explosive charge portion 44A and the explosive charge portion 44B in view of the strength of aluminum which is a joint tube.
In the present embodiment, the P-4 explosive is loaded into the explosive charge portion 44A, the hollow portion 45, and the explosive charge portion 44B.
[0060]
When the P-4 explosive is loaded into the explosive charge portion 44A, the hollow portion 45, and the explosive charge portion 44B, an aluminum thin plate 91 is attached to the outside of the opening on one side end of the male joint 40A via an adhesive, and is closed. And loading from the opening on the other end. And after loading, the aluminum thin plate 92 is affixed on the outer side of the opening part on the other side via an adhesive and closed.
Next, as shown in FIG. 3, the female joint 40 </ b> B has an aluminum cylindrical tube body having a hollow portion (explosive charge loading hole) 55 that is open on one side and the other side and into which the explosive charge 44 can be loaded. It is made by processing 41b.
[0061]
At one end, a notch recess 56 having a notch step shape in which an insertion portion 47 and a notch step portion 46 of the male joint can be inserted at the entrance, and a deep portion of the notch recess 56 are provided. An insertion portion 57 is formed which has an inner diameter so that the notch step portion 46 of the insertion portion 47 can be rotated and moved in the radial direction.
A screw portion 58 is formed on a part of the outer periphery of the trunk portion 40B1 (about 20 mm from the tip portion) so as to be screwed with the cord-shaped explosive introduction pipe 65 at the other end portion.
[0062]
On the outer periphery of the insertion portion 57, a head 59 is formed which is formed larger than the outer diameter of the body portion 40B1 via a stepped portion. The head portion 59 is provided with an insertion portion 57 and two hole portions 60 on the outer peripheral end face of the insertion portion 57. The hole 60 incorporates a stopper 61 made of a cylindrical pin and a spring 62 that presses the stopper 61.
[0063]
In the hollow portion 55, an explosive agent portion 54A and an explosive agent portion 54B are formed.
In the female joint 40B of the present embodiment, the hollow portion 55 is smaller than the inner diameters of the explosive charge portion 54A and the explosive charge 54B due to the restriction due to the outer diameter (φ16 mm) of the cord-like explosive 30 as in the male joint 40A. It is formed with an inner diameter. In addition, the explosive charge part 54A and the explosive charge part 54B make the explosive charge 54 easily explode by increasing the pressure receiving area that receives the impact (detonation) from the cavity 55.
[0064]
When the explosive 54 is loaded into the hollow portion 55, the explosive charge portion 54A, and the explosive charge portion 54B, the aluminum thin plate 92 is attached to the outside of the one end opening portion of the female joint 40B with an adhesive to block the explosive charge 54. And loading from the opening on the other end. And after loading, the aluminum thin plate 63 is affixed on the outer side of the opening part on the other side with an adhesive, and is closed. Next, the connection between the male joint 40A and the female joint A40B in the present embodiment will be described with reference to FIG. Here, the explosive charge is omitted for explanation.
[0065]
First, as shown in FIG. 4A, the insertion portion 47 of the male joint 40A is opposed to the insertion portion 57 of the female joint 40B.
Next, as shown in FIG. 4B, the insertion portion 47 of the male joint 40A is rotated 90 ° counterclockwise to move the insertion portion 47 to a position where it can be inserted into the insertion portion 57. Next, the insertion portion 47 is inserted. Is inserted into the insertion portion 57.
[0066]
Next, as shown in FIG. 4C, when the insertion portion 47 is further pushed in, the end surface of the flange portion 49 of the male joint 40A comes into contact with the stopper 61 of the female joint 40B, and the spring 62 is compressed. To go.
Next, as shown in FIG. 4 (D), the male joint 40A is rotated 90 ° to the left, and when the stopper fixing hole 50 and the stopper 61 of the male joint 40A face each other, they are pressed by the spring 62. The stopper 61 enters the stopper fixing hole 50, and both joints 40A and 40B are fixed.
[0067]
At that time, the explosives loaded in the joints 40A and 40B are also in contact with each other at the end face of the aluminum thin plate.
In this embodiment, the stopper fixing hole 50 is perforated, but it may be formed in a groove into which the stopper 61 enters.
Next, the cord explosive introduction pipe 65 to which the connecting tool 33 of the cord explosive 30 is attached will be described.
[0068]
As shown in FIG. 5, the cord-shaped explosive introduction tube 65 is open at one side and the other side and penetrates, and is connected to each joint (male joint, female joint) 40A, 40B on one side. And an aluminum cylindrical shape having an explosive loading cavity portion 67 that communicates with the joint connection portion 66 and can be loaded with an explosive and a cord explosive introduction cavity portion 68 that is connected to the cord explosive 30 on the other side. It is made by processing the pipe body 65a.
[0069]
On the inner peripheral surface of the joint connection portion 66, a female screw 66a that can be screwed and joined to each joint 40A, 40B is cut.
The explosive loading cavity 67 is smaller than the inner diameter of the cord explosive introduction cavity 68 so that the cord explosive 30 stops at the boundary between the cord explosive loading cavity 67 and the cord explosive introduction cavity 68. An inner diameter is formed.
[0070]
As described above, two cord explosive introduction pipes 65 are required to connect the male joint 40A and the cord explosive 30 and the female joint 40B and the cord explosive 30.
Next, the explosive 69 and the liner 70 disposed inside the cord-shaped explosive introduction pipe 65 will be described with reference to FIG. 6 (here, the liner 70 is made of thin copper in a conical shape, and the maximum diameter of the circle is set). φ14 mm).
[0071]
First, a conical liner 70 is inserted into the explosive loading cavity portion 67 for loading the explosive 69 so that the apex side is on the joint connector 40A, 40B side.
Next, the explosive 69 is loaded in contact with the liner 70. At this time, the explosive 69 is also loaded into the internal space portion of the joint connection portion 66 so that there is no gap between the liner 70 and the internal space portion.
[0072]
Here, the joint connecting portion 66 of the cord explosive introduction pipe 65 and each joint (male joint, female joint) 40A, 40B can be screwed together.
As shown in FIG. 6D, in the case of the cord-shaped explosive introduction pipe 65 in which the liner 70 is not disposed, the explosive 69 is loaded in the internal space of the explosive loading cavity 67 and the joint connecting portion 66 without a gap.
[0073]
  Next, as shown in FIG. 6, a specific example of connecting and arranging the cable-shaped explosive 30 to the cable-shaped explosive introduction pipe 65 will be described and the operation thereof will be described.
  Example 1
  In FIG. 6A, the liner 70 and the P-4 explosive 69 are disposed in the explosive loading cavity 67 of the cord explosive introduction pipe 65. As shown in FIG. 8, by inserting a cord-shaped explosive 30 fitted at one end into a liner storage tool 36 loaded with a P-4 explosive 71 without placing a liner into a cord-shaped explosive introduction cavity 68. The cord-like explosive introduction tube 65 and the cord-like explosive 30 are fixed (Claim 1,12Corresponding).
[0074]
  As a result, the detonation of the P-4 explosive 69 generates a liner 70 as a high-temperature jet by the explosion from the explosive loading cavity 67 side, and is inserted into the cord explosive introduction cavity 68. Explode to explosive 30.
  Example 2
  In FIG. 6B, the liner 70 and the P-4 explosive 69 are arranged in the explosive loading cavity 67 of the cord explosive introduction pipe 65. A cord-like explosive introduction pipe 65 and a cord-like shape are inserted by inserting a cord-like explosive 30 inserted into one end portion into a liner storage tool 36 in which a liner 35 and a P-4 explosive 37 are arranged into a cord-like explosive introduction cavity 68. Fixed with explosive 30 (claim)2, 13, 14Corresponding to).
[0075]
As a result, the detonation of the P-4 explosive 67 generates a liner 70 into a high-temperature jet due to the explosion from the explosive loading cavity 67 side, and propagates to the cord-like explosive introduction cavity 68 side.
Then, this jet generates a liner 35 of the liner storage tool 36 to be inserted into the cord explosive introduction portion 65 into a high temperature jet and is transmitted to the cord explosive 30 inserted in the cord explosive introduction cavity 68. Explode.
[0076]
Example 3
FIG. 6 (C) shows a state where the cord explosive introduction pipe 65 of the cord explosive introduction pipe 65 is inserted by inserting the cord explosive 30 inserted into one end portion into the liner storage tool 36 provided with the liner portion 34 into the cord explosive introduction cavity 68. The cord explosive introduction pipe 65 and the cord explosive 30 are fixed by being inserted into the cord explosive introduction cavity 68.
[0077]
A liner 70 and a P-4 explosive 69 are loaded in the explosive loading cavity 67 of the cord explosive introduction pipe 65, and a P-4 explosive 69 is loaded in the space of the joint connecting portion 66. As a result, the detonation of the P-4 explosive 37 generates the liner 35 into a high-temperature jet by the transmission from the cord-shaped explosive 30 side and transmits it to the joint connection side. And this jet produces | generates the liner 70 arrange | positioned in the explosive loading cavity 67 to a high temperature jet, and transmits to the P-4 explosive 69 currently loaded.
[0078]
Example 4
6 (D) shows a state where a cord-like explosive introduction pipe 65 and a cord-like explosive introduction pipe 65 are inserted into a cord-like explosive introduction cavity 68 by inserting a cord-like explosive 30 fitted into one end portion into a liner storage tool 36 provided with a liner portion 34. The cord-shaped explosive 30 is fixed.
There is no liner in the explosive loading cavity 67 of the cord explosive introduction pipe 65, and a P-4 explosive 69 is loaded together with the joint-connected space. As a result, the detonation of the P-4 explosive 37 generates the liner 35 into a high-temperature jet by the transmission from the cord-shaped explosive 30 side and transmits it to the joint connection side. Then, this jet is transmitted to the P-4 explosive 69 loaded in the explosive loading cavity 67 or the like.
[0079]
As in these specific examples 1 to 4, the arrangement of the liner 35 or 70 is basically on the detonation traveling direction side, but even if the liner is arranged on both, it does not hinder the explosion effect. . In the experiment of the present inventor, when the transmission was confirmed by intentionally opening a gap between the liner of the cable-shaped explosive introduction pipe of the cable-shaped explosive and the liner surface put in the liner housing, the gap was 2 mm. It was confirmed that all of the bombs were transmitted at -15 mm.
[0080]
Moreover, even if the liners were arranged facing each other and the circumferential surfaces of the liners were brought into contact with each other so that the gap was 0 mm, the explosion was transmitted without any problem.
Next, based on FIG. 9, the assembly of the whole cord explosive device formed by connecting the cord explosive 30 with the cord explosive connecting device 20 will be described (corresponding to claims 20 to 25). In FIG. 9, an example of one female joint 40B will be described in detail, but the male joint 40A shown in FIG. 2 and the female joint 40B shown in FIG. 3 are as shown in FIG. The description is omitted because it is connected by fitting.
[0081]
Further, the cord-shaped explosive introduction pipe 65 connected to the female joint 40B has a connection configuration using FIG.
First, as shown in FIG. 9A, a cord-shaped explosive introduction tube 65 is attached to the female joint 40B.
Next, as shown in FIG. 9B, a cord-shaped explosive (here, 30 m long) 30 accommodated in the liner storage tool 36 is prepared.
[0082]
Two reinforcing ropes (here, polyethylene ropes used for packing) 80 are attached along the length of the cord-shaped explosive 30 longer than the cord-shaped explosive 30.
The reinforcing rope 80 and the cord-shaped explosive 30 are fixed with an adhesive vinyl tape every predetermined distance from the top of the reinforcing rope 80.
Next, as shown in FIG. 9C, the cord-shaped explosive 30 is inserted into the cavity 68 of the cord-shaped explosive introduction tube 65 connected to the female joint 40B.
[0083]
Then, the reinforcing rope 80 that runs along the entire length of the cord-shaped explosive 30 is wound around the trunk portion 40B1 with a spider string (or a wire made of stainless steel or the like) 82 at a position where the reinforcing rope is fixed between the convex portions 51.
Next, as shown in FIG. 9 (D), a heat shrinkable tube 83 is placed at a distance of about 10 m in the direction of the cord-shaped explosive from the top of the spider string 82 to which the reinforcing rope 80 is fixed, and is heated and shrunk with steam, hot air or the like. Fix it.
[0084]
The heat shrinkable tube 83 is previously bent on the cord-shaped explosive 30 with the reinforcing rope 80 wound around.
As a result, when the cord-shaped explosive 30 is expanded by flying with a rocket or the like, a tensile force is applied to the cord-shaped explosive 30, and the force that the cord-shaped explosive 30 and the liner insertion tool 36 try to come out from the cord-shaped explosive introduction pipe 65. However, since the reinforcing rope 80 and the heat shrinkable tube 83 are fixed to the female joint 40B, it is possible to prevent the cord explosive 30 and the liner insertion tool 36 from coming out of the cord explosive introduction portion 63.
[0085]
Next, as shown in FIG. 9 (E), a Tetron (registered trademark) sleeve (hereinafter referred to as a sleeve) 84 that is 20 to 30 cm longer than the cord-shaped explosive 30 is placed. In the sleeve 84, a thread (here, a kite thread) is passed in advance in the manufacturing process. For the sleeve 84, Kevlar (registered trademark) or the like may be used.
[0086]
When this thread is pulled by tying and fixing one end of the reinforcing rope 80 attached to the cord-shaped explosive 30, the female passing through the sleeve 84 from the end of the cord-shaped explosive 30 is connected to the cord-shaped explosive 30. The mold joint 40B can be covered.
Here, the outer periphery of the sleeve 84 is fixed around two sleeve fixing grooves 76 and 77 provided between the two convex portions 75a and 75b formed on the body portion 40B1 of the female joint 40B with a fixing wire.
[0087]
Next, as shown in FIG. 9 (F), the tip end portion of the sleeve 84 is folded back, and the sleeve 84 is wound around and fixed to the two sleeve fixing grooves 76 and 77 by fixing wires.
Thus, as shown in FIG. 9G, the connection between the female joint 40B and the cord-shaped explosive 30 is completed.
[0088]
Next, an experiment was conducted on fixing the female joint and the sleeve 84, and the result is shown.
Experiment 1
In the case where the sleeve 84 is fixed to the female joint 40B by winding a wire from above the sleeve 84 with only one of the sleeve fixing groove 76 of the female joint 40B or the sleeve fixing groove 76, the sleeve 84 and the female joint When a tensile force was applied during 40B, the sleeve 84 slipped out of between the wire and the female joint 40B with a tensile force of about 200 kgf.
[0089]
Experiment 2
When the sleeve 84 is wound around both the sleeve fixing groove 76 and the sleeve fixing groove 77 of the female joint 40B from the top of the sleeve 84 and the sleeve 84 and the female joint 40B are fixed, the sleeve 84 and the female joint 40B are fixed. When a tensile force was applied between them, the wire wound with a tensile force of about 1000 kgf was loosened, and the sleeve 84 was pulled out.
[0090]
Experiment 3
A sufficient amount of the sleeve 84 that has been passed through the female joint 40B is folded back, and a wire is wound around the sleeve 84 folded back by both the fixing groove 76 and the sleeve fixing groove 77, so that the sleeve 84 is female. The joint 40B is fixed.
When the sleeve 84 is folded and the sleeve 84 is fixed with a wire, if a tensile force is applied between the sleeve 84 and the female joint 40B, the connecting portion is not damaged even if a tensile force of about 2000 kgf is applied. Breakage occurred in other parts.
[0091]
Experiment 4
Even when a commercially available punch band is used instead of a wire in the same number as the number of wires for the connection between the sleeve 84 and the female joint 40B, the same applies when a tensile force is applied between the sleeve 84 and the female joint 40B. Strength results were obtained.
Next, the female joint 40B to which the cord explosive 30 is connected as described above and the male joint 40A to which the cord explosive 30 is connected by the same method as the female joint 40B are combined as shown in FIG. By doing so, a cord-shaped explosive device 20 having a predetermined length can be obtained.
[0092]
In the present embodiment, the cable-shaped explosive 30 with the male joint 40A attached is 30 m, and the cable-shaped explosive 30 with the female joint 40B attached is 30 m, which are connected by both joints 40A and 40B, and slightly over 60 m. Although described as the cord explosive device 20, when the cord explosive device 20 extends to 100 m or more, the end of the cord explosive 30 extending to the rocket (flying object) side is fitted into the liner housing 36. The cord explosive 30 is inserted into the cord explosive introduction pipe 65 and fixed.
[0093]
And the joint connection part of this cord explosive introduction pipe 65 and the cord explosive connection part of one joint are screwed together. Furthermore, this joint and the other joint are fitted into a long cord explosive device. It becomes possible by repeating this.
In addition, the fuze for detonating the cord explosive 30 is usually used by being disposed on the cord explosive 30 on the side opposite to the rocket (flying object) at the site where buried explosives are processed.
[0094]
Therefore, when the explosive explosive 30 wound up and stored in the storage container is used for the disposal of buried bombs such as landmines such as minefields, it is rapidly and impacted by the rocket projection from the wound state. No explosive damage.
Further, the damage caused by the rocket projection is about 10 m (from the empirical rule) from the front end portion of the cord-shaped explosive 30, so that this range of length may be covered.
[0095]
In addition, the cord explosive device 20 having a length of 100 m or more is possible, and even when a gap is generated between the cord explosive and the connecting portion at the time of strong expansion by projection of the cord explosive rocket or the like, Good explosiveness can be maintained.
(Second embodiment)
FIG. 10 shows a cord explosive device 100 according to the second embodiment of the present invention.
[0096]
A cord-shaped explosive device 100 according to the present embodiment is a cord-shaped explosive device in which a cord-shaped explosive 30 formed to 10 m to 30 m is connected to 60 m and 120 m as required.
The cord explosive device 100 according to the present embodiment is the cord explosive according to the first embodiment in that the cord explosive 30 is directly inserted into the cord explosive introduction pipe 65 without using the liner storage tool 36. Different from the device 20.
[0097]
Also in the cord-shaped explosive device 100 according to the present embodiment, since the liners 70 are disposed in the male joint 40A and the female joint 40B, the same operational effects as in the first embodiment can be achieved.
(Third embodiment)
Another embodiment of the cord explosive and the cord explosive device using the cord explosive will be described.
[0098]
In the first embodiment, RDX 70% to 85% having relatively fine particles as the main component of the solid compound explosive substance is weighed, and further 15% to 30% of a binder (silicone resin, etc.) is weighed and mixed to be plastic. Although the case where the explosive (here, the plastic explosive) 31 is used has been described, the present invention is not limited to this, and the following plastic explosive can also be used.
[0099]
RDX 70% to 85% with relatively fine particles as a solidified compound explosive substance as a main component, styrene block copolymer (15% to 30%) and aliphatic oil as thermoplastic resins having a melting point of 60 ° C to 100 ° C A plastic explosive is made by heat-mixing a binder 15% to 30% obtained by mixing (70% to 85%).
As solidified explosives, PETN (pen slit), HMX (cyclotetramethylenetetranitramine) and the like can be used in addition to RDX (trimethylenetrinitroamine).
[0100]
As the aliphatic oil, a mixture of paraffin oil, naphthenic oil and aromatic hydrocarbon is suitable. As this mixed oil, for example, there is SHELLFLEX 371 (Shell Chemical Company), and its composition is paraffinic oil 54%, naphthenic oil 44%, and aromatic hydrocarbon 2%.
Further, as a styrene block copolymer of a thermoplastic resin, there is Kraton G (Shell Chemical Company), and among them, Kraton G-1652 (Shell Chemical Company).
Company).
[0101]
This Kraton G-1652 (Shell Chemical Company) is a block copolymer composed of polystyrene-rubber intermediate block-polystyrene. The rubber intermediate block is a polyolefin, and this polyolefin has good compatibility with naphthene oil.
In addition, since the melting point of the binder (thermoplastic rubber) varies depending on the ratio between the aliphatic oil and the thermoplastic resin, in this embodiment, the melting point is set to 8: 2 between the aliphatic oil and the thermoplastic resin. Was 70 ° C.
[0102]
As a result, a cord-like explosive that is long and flexible and has a strong waist (with high tensile strength) can be obtained.
By the way, it was stretched by about 20% when pulled by hand, and the test result of the Amsler type tensile tester was 3 to 5 kgf (30 to 50 N).
Next, using this explosive, a rope-shaped cord explosive is produced.
[0103]
First, a weighed aliphatic oil and a heated thermoplastic resin are stirred and mixed to make a binder, and then weighed RDX and the binder are heated and mixed in a steam kettle to make a plastic explosive. For this mixing, manual mixing or mechanical mixing using a spatula can be applied.
Then, this heat-mixed plastic explosive is stored in the molder chamber of the molding apparatus in a heat-retaining state, and the handle of the molder is rotated clockwise to advance the buttocks in the chamber toward the throttle port. A plastic explosive is extruded from a nozzle hole formed in the throttle port and formed into a circular rope shape.
[0104]
The rope-shaped explosive expelled from the nozzle hole is immediately cooled by the cooler water.
At this time, the dose in the chamber of the molding machine was about 2100 g, and the rope-like cord explosive had a diameter of 20 mm and a length of about 5 m. Needless to say, it is possible to produce a predetermined cord explosive of 5 m or more by increasing the dose.
[0105]
This cord explosive is a strong material that stretches by about 20% when pulled by hand, and is flexible enough to be wound around a cylindrical piece such as a bobbin.
Next, this cord-shaped explosive is inserted into the shrinkable tube and covered with a flexible protective member.
[0106]
First, a connecting rod is made by connecting three support rods for gardening (φ9 mm × length 1.8 m) with gummed tape.
Then, the tip of the cord-shaped explosive and the tip of the connecting rod are connected with a gum tape to connect the connecting rod and the cord-shaped explosive.
In addition, the tip of the connecting rod connected to the cord-shaped explosive is attached to the tip opening of a separately prepared shrinkable tube having a thickness of 0.3 mm × φ25 mm × length of about 5 m (Sumitube C “Sumitomo Electric Co., Ltd.”). Insert.
[0107]
Then, as the tip of the connecting rod is traversed, the cord explosive is accommodated in the contractile tube as a whole cord explosive.
The heat-shrinkable tube is heated by passing the cord-shaped explosive accommodated in the shrinkable tube so as to be hidden in the heating container of the heating device (in which hot water at 100 ° C. is accommodated). .
[0108]
The heating device includes a heating container that contains hot water (hot water) and a cord-shaped explosive, and a heater that heats the hot water. In this embodiment, the heating container uses a polyethylene container, and the heater uses steam. Use a hose.
This steam hose is inserted into hot water in a polyethylene container, and steam is discharged to keep the hot water at a constant temperature (the temperature is usually kept at 90 ° C. to 100 ° C.).
[0109]
As a result, the contractible tube contracts along the explosive shape within a range of physical properties, so that a single cord explosive of about 5 m having a protective member can be manufactured.
Since this single cord explosive is provided with a protective member, it can improve the strength of the entire cord explosive and withstand strong pulling and bending. It also protects the explosive itself.
[0110]
The heating method uses hot water to maintain this temperature, and steam is sent to the hot water with a steam hose, but as another heating method, it is possible to directly apply steam heat from the steam hose, It is also possible to apply hot air from a dryer or the like, pour hot water, or place it in a dry high-temperature bath.
Next, one side end of the cord-shaped explosive having this protective member is heated again and softened to form a liner portion. This liner portion is performed in the same manner as the formation of the liner portion in the plastic cord explosive (plastic cord explosive), and is omitted here.
[0111]
Next, a composition example of a plastic explosive will be given.
“Composition Example 1”
80% RDX and 20% binder (80% aliphatic oil and 20% thermoplastic resin) are mixed.
“Composition Example 2”
RDX 75% and binder 25% (aliphatic oil 80% and thermoplastic resin 20%) are mixed.
[0112]
“Composition Example 3”
70% RDX and 30% binder (70% aliphatic oil and 30% thermoplastic resin) are mixed.
“Composition Example 4”
70% PETN and 30% binder (80% aliphatic oil and 20% thermoplastic resin) are mixed.
[0113]
【The invention's effect】
According to the present invention, the following effects can be obtained.
(1) Since the liner portion is disposed on the rope-shaped cord explosive having flexibility, the explosiveness to the explosive having proximity or a gap is good.
(2) By providing a reinforcing rope to the explosive having flexibility, a cord-shaped explosive having a high tensile strength can be obtained.
(3) Molded into a rope-like cord explosive with flexibility, and the explosive binder can be bonded to each other by using the same material resin, producing cord-shaped explosives in a predetermined length It becomes possible to do.
[0114]
(4) Since the explosive is disposed in the connecting portion connected to the cord explosive and the liner portion is disposed at the end portion, the explosive property to the explosive having proximity or a gap is good.
(5) Since the cord explosive device in which the liner portion is arranged and the connecting portion in which the liner portion is arranged are connected to form a cord explosive device, even when a gap is generated between the cord explosive and the connecting portion. , The transmission can be performed reliably.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing an outline of joint connection of a cord-shaped explosive device according to a first embodiment of the present invention.
2A is a cross-sectional view of the male joint in FIG.
(B) It is an end view of the male joint in FIG.
3A is a cross-sectional view of the female joint in FIG.
(B) It is an end view of the female joint in FIG.
4 is an explanatory view showing an outline of joint assembly for connecting both joints in FIG. 1; FIG.
5A is a cross-sectional view of a cord-shaped explosive introduction tube provided with the liner portion in FIG. 1. FIG.
(B) It is a modification of the cord explosive introduction pipe | tube in FIG. 1, and is sectional drawing of the cord explosive introduction pipe | tube without a liner part.
FIG. 6 is a cross-sectional view showing a specific example of liner attachment of a cord explosive introduction tube used in the present invention.
7A is a cross-sectional view showing the liner explosive container for the cord explosive in FIG. 1. FIG.
(B) It is an end view which shows the liner storage tool of the cord explosive in FIG.
(C) It is sectional drawing which shows the state which attached the cord explosive to the liner storage tool of the cord explosive in FIG.
FIG. 8A is a cross-sectional view showing a state in which a cord explosive is attached to a liner storage tool without a cord explosive liner used in the present invention.
(B) It is an end view of (A).
9 is an explanatory view showing an assembly configuration on the female joint side of the cord explosive device in FIG. 1; FIG.
FIG. 10 is a cross-sectional view showing an overall outline of a cord explosive device according to a second embodiment of the present invention.
FIG. 11 shows a general outline of a conventional cord explosive and a cord explosive device.
[Explanation of symbols]
20, 100 cord explosive device
30 Cord explosive
31 Plastic explosive
32 Protection member
33 Connecting tools
34 Liner
36 Liner storage
35 liner
37 Explosives with explosive speed higher than the plastic explosive 31 (P-4 explosives)
40 Cord explosive connection device
40A male joint
40A1 trunk
40B Female joint
40B1 trunk
41a, 41b tube
42a, 42b Joint connection part
43a, 43b
44 Explosives
44A Explosives Department
44B Explosives Department
45 Cavity (Explosive Loading Hole)
46 Notch Step
47 Protruding insert
48 Screw part
49 Buttocks
50 Stopper fixing hole
54 Explosives
54A Explosives Department
54B Explosives Department
55 Cavity (Explosive Loading Hole)
56 Notch recess with notch step
57 Plug
58 Screw part
60 holes
61 Stopper
62 Spring
65 Cord explosive introduction tube
66 Joint connection
67 Explosive loading cavity
68 Cavity for cord explosive introduction
69 Explosives
70 liner
71 P-4 explosive
75a, 75b Convex part
76, 77 Sleeve fixing groove
80 Reinforcement rope
82 Samurai string (or wire made of stainless steel)
83 Heat Shrink Tube
84 Tetron (registered trademark) sleeve

Claims (25)

A plastic explosive formed by extruding a long cord;
A protective member covering the entire length of the outside of this plastic explosive;
A connector provided on at least one side end of the plastic explosive ,
The connector is composed of a cylindrical body that covers an end portion of the plastic explosive covered with the protective member, and an explosive having an explosive speed than the plastic explosive loaded in the cylindrical body. A cord-shaped explosive. A plastic explosive formed by extruding a long cord;
A protective member covering the entire length of the outside of this plastic explosive;
A connector having a liner portion in which a liner for generating a jet is disposed, and provided at at least one side end of the plastic explosive;
Consists of
A cord-shaped explosive in which the liner portion is provided with an explosive having an explosion speed higher than that of the plastic explosive. In the cord-shaped explosive according to claim 2,
The connecting tool is composed of a tubular body that covers an end portion of the plastic explosive covered with the protective member, and a liner portion disposed in the tubular body. . In the cord-shaped explosive according to claim 1 or claim 3,
A cord explosive characterized in that an end of the plastic explosive covered with the protective member and the cylindrical body are fixed by a fixing member . In the cord-shaped explosive according to any one of claims 1 to 3 ,
A cord-shaped explosive characterized in that the plastic explosive is a plastic explosive. In the cord-shaped explosive according to any one of claims 1 to 3 ,
A cord-shaped explosive characterized in that the plastic explosive is a mixture of a solidified explosive and a binder . In the cord-shaped explosive according to claim 6 ,
The binder is a cord-shaped explosive characterized in that it is cured into a long cord-like body and then reaction-cured, and after curing, is used as an adhesive when connecting one end surfaces of the plastic explosives. In the cord-shaped explosive according to claim 7 ,
A cord-shaped explosive characterized in that the binder is silicon resin . In the cord-shaped explosive according to any one of claims 1 to 3 ,
A cord-shaped explosive characterized in that the protective member is a laminated tube . In the cord-shaped explosive according to claim 1 or claim 2 ,
The cord explosive, wherein the protective member is a contractible tube that contracts by heat or light . In the cord-shaped explosive according to claim 2 ,
The cord explosive characterized in that the liner is made of at least one material selected from copper, aluminum, tungsten, titanium or alloys thereof, aluminum oxide, boron carbide, silicon carbide, and graphite . A cord-like explosive connecting device for connecting the cord-like explosive according to claim 1 and the connection tool to transmit the cord-like explosive,
A tubular tube penetrating from one side to the other and having an explosive inside,
A joint connecting portion provided on one side of the tubular body;
A liner having a liner for generating a jet, and an explosion transmitting portion provided on the other side of the tube;
Comprising a pair of joint bodies comprising
A cord-shaped explosive connection device, wherein the pair of joint bodies are coupled and separated through the joint coupling portion . A plastic explosive formed by extruding a long cord;
A protective member covering the entire length of the outside of this plastic explosive;
A connector having a liner portion in which a liner for generating a jet is disposed, and provided at at least one side end of the plastic explosive;
A cord-shaped explosive composed of
In the cord explosive connection device for connecting through the connecting tool and transmitting the cord explosive,
A tubular tube penetrating from one side to the other and having an explosive inside,
A joint connecting portion provided on one side of the tubular body;
A liner portion provided with a liner for generating a jet or a filling portion loaded with an explosive having an explosive speed than the plastic explosive, and an explosion transmission portion provided on the other side of the tubular body;
Comprising a pair of joint bodies comprising
The pair of joint bodies are coupled and separated via the joint coupling portion.
A cord-shaped explosive connection device characterized by that. A cord-shaped explosive connecting device for connecting the cord-shaped explosive according to claim 2 and the connection tool to transmit the cord-shaped explosive,
A tubular tube penetrating from one side to the other and having an explosive inside,
A joint connecting portion provided on one side of the tubular body;
A pair of joint bodies comprising: a liner part in which a liner for generating a jet is disposed or a filling part loaded with an explosive having an explosive speed than the plastic explosive ; Consists of
The pair of joint bodies are coupled and separated through the joint connecting portion. The cord-shaped explosive connection device according to any one of claims 12 to 14 ,
The pair of joint bodies includes a male joint in which the joint connecting portion provided at the tip portion is formed in a convex shape, a female joint in which the joint connecting portion provided in the tip portion is formed in a concave shape, and both joints A cord-shaped explosive connection device, comprising: a fixing portion that engages and fixes both joint connecting portions provided at the distal end portion . The cord-like explosive connection device according to claim 15 ,
The fixing portion is provided with a stopper fixing hole for locking with the female joint on the male joint side, and with a stopper for locking with the stopper fixing hole on the female joint side. Characteristic explosive connection device. The cord-shaped explosive connection device according to any one of claims 12 to 14 ,
The explosive explosive connecting device, wherein the explosive portion is formed in a cylindrical explosive introduction pipe coupled to the other side of the tubular body . The cord-shaped explosive connection device according to claim 17 ,
The cord explosive introduction pipe is a cylindrical single tube having an explosive loading cavity and a cord explosive introduction cavity inside and a connecting portion connected to the other side of the pipe. A cord-shaped explosive connection device. Cord-like explosive device, characterized in that the cord-like explosive according to claim 1 wherein formed by connecting to via cord-like explosive connection device according to claim 12. A plastic explosive formed by extruding a long cord;
A protective member covering the entire length of the outside of this plastic explosive;
A connector having a liner portion in which a liner for generating a jet is disposed, and provided at at least one side end of the plastic explosive;
In the trabecular explosives configured, cord-like explosive apparatus characterized by comprising linked via a cord-like explosive connection device according to claim 13. Cord-like explosive device characterized by comprising a cord-like explosive according to claim 2, wherein linked via a cord-like explosive connection device according to claim 14. In the cord-shaped explosive device according to claim 20 or 21 ,
The explosive explosive device is characterized in that the explosive portion and the cord explosive are opposed to each other via a liner portion formed on the explosive portion and the explosive explosive. In the cord-shaped explosive device according to claim 20 or 21 ,
The explosive device and the cord explosive are opposed to each other through a liner portion formed on either the explosive portion or the cord explosive. In the cord-shaped explosive device according to claim 20 or 21 ,
The liner explosive device characterized in that the liner portion provided in the connector of the cord explosive has a liner arranged so as to generate a jet in the explosion traveling direction. In the cord-shaped explosive device according to claim 20 or 21 ,
The liner explosive device characterized in that the liner portion provided in the explosive portion of the cord explosive connecting device is provided with a liner so as to generate a jet in the explosion traveling direction.

Images