JP2000220997A - Discharge impact fracture apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a discharge impact fracture apparatus capable of improving a fracture efficiency. SOLUTION: In the discharge impact fracture apparatus 1 for breaking a material to be broken by supplying an electric energy to a metal fine wire 14, disposed in a metal cylindrical container 12 charged with an explosive substance 11 in a short time to abruptly melt vaporize the wire 14, exploding the substance 11 by an impact force generated when melt vaporized to break the material; the wire 14 is disposed along an axial center of a cylindrical sidewall 21 of the container 12, a welded part M is provided along the wire 14, and further the wire 14 is disposed in the container so that a shortest distance from the wire 14 to the sidewall 21 of the container 12 becomes shorter than a shortest distance from an end of the wire 14 to an inner surface of the container 12.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a discharge impact destruction device for destroying an object to be destroyed such as concrete or rock using high-voltage discharge energy.

[0002]

2. Description of the Related Art Conventionally, dynamite has been used to destroy objects to be destroyed such as concrete and bedrock, but there is a danger in handling and the like.

In order to eliminate this danger, recently,
A discharge impact destruction device using discharge energy has been proposed.

[0004] As shown in FIG. 8, in this discharge impact destruction device 51, a thin metal wire 64 is inserted via an electrode rod 63 into a cylindrical container 62 filled with a liquid 61 such as water as a destruction substance. The high-voltage electrical energy charged in the capacitor is supplied to the thin metal wire 64 via the electrical wiring 65 in a short time (for example, several tens of microseconds). The thin metal wire 64 is melted and vaporized at once, and the object 71 is destroyed by the expanding force of the liquid generated by the expanding force (impact force) at that time.

[0005]

When the object to be destroyed floating or buried in the air or in a fluid substance such as sand or water is to be destroyed by the discharge impact destruction device 51, a cylinder is required. The cylindrical container 61 is disposed in the vicinity of the cylindrical container 61. Usually, the cylindrical container 61 is formed of a uniform material, and it is not clear which part bursts. When it is ruptured, the object to be destroyed is not destroyed.
If the pieces burst apart, there is also a disadvantage that the breaking force is diffused and the breaking efficiency is reduced.

Accordingly, an object of the present invention is to provide a discharge impact breakdown device capable of improving the breakdown efficiency.

[0007]

In order to solve the above-mentioned problems, a discharge impact crushing device of the present invention supplies electric energy to a molten vaporized substance disposed in a container filled with an explosive substance in a short time. A discharge impact destruction device for exploding the explosive substance to destroy an object to be destroyed by an impact force generated at the time of the melt vaporization, wherein the container has a fragile portion. A weld is provided on the side wall, or a notch or a hole is provided on the side wall, and the molten vaporized substance is arranged along the weld, the notch or the hole. is there.

Further, in the above structure, the molten vaporized material is formed in a linear shape, and the molten vaporized material is more than the shortest distance between the end of the molten vaporized material and the end wall of the metal container facing each other. And the molten vaporized substance is arranged in the container so that the shortest distance between the container and the side wall of the container is shorter,
Further, the thickness of the side wall of the container is made thinner than that of each end wall.

According to the above configuration, the explosive substance explodes due to the impact force at the time of melt vaporization of the molten vaporized substance. At this time, the vessel has a fragile portion such as a welded portion, a notch portion, or a hole portion. Since the container is provided, the container is arranged so that the fragile portion faces the object to be destroyed, so that the object to be destroyed can be reliably destroyed.

In addition, the molten vaporized material is arranged so as to be located closest to the fragile portion, and the thickness of the side wall portion of the container provided with the fragile portion is made thinner than that of the end wall portion. Destruction of the object can be reliably performed.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A discharge impact breaking device according to an embodiment of the present invention will be described below with reference to FIGS.

As shown in FIGS. 1 and 2, the discharge impact destruction apparatus 1 includes a metal cylindrical container 12 filled with, for example, nitromethane as an explosive substance 11, A pair of electrode rods 13 inserted into the conductive material 11, a thin metal wire (for example, a copper wire is used) 14 which is an example of a molten vaporized substance connected between the tip portions of the electrode rods 13, and An electric energy supply device (not shown) for supplying high-voltage electric energy to the base ends of the pair of electrode rods 13 via the electric wiring 15 in a short time.

The cylindrical container 12 is formed by bending a metal plate into a cylindrical shape and welding side edges of the metal plate to each other by welding M (hereinafter, referred to as M).
A cylindrical side wall 21 formed as a welded portion (corresponding to a fragile portion) and an end wall portion 22 made of a circular metal plate attached to the upper and lower ends of the side wall portion 21 by welding, respectively. It is composed of

The electrode rod 13 is connected to one end wall 2.
2A, the metal thin wires 14 are vertically arranged, that is, as shown in FIG.
In order to dispose along one axis, one electrode rod 13A
Is shortened so as to be located above the inside of the cylindrical container 11, the other electrode rod 13B is inserted downward and its end is bent upward by 180 degrees, and both electrode rods 13A, 13B Metal wire 14 between the opposite ends of
Are connected and arranged.

Further, the thin metal wire 14 is used for the cylindrical container 1.
The second side wall 21 and the end wall 22 are provided at positions closest to the welded portion M.

[0016] That is, the weld (weld line) M and towards the shortest distance L ₁ between the metal thin wires 14, the shortest distance L ₂ to the side wall portion 21 opposite to the welded portion M around the thin metal wires 14
And the shortest distance L
₁ is shorter than the shortest distances L ₃ and L ₄ between both ends of the thin metal wires 14 and the corresponding end walls 22.

As described above, by arranging the thin metal wire 14 at a position where the distance to the welded portion M is the shortest of the distance to the cylindrical container 12 with respect to the thin metal wire 14, the melting of the thin metal wire 14 is achieved. The expansion force, that is, the impact force generated at the time of vaporization is reliably transmitted to the welded portion M. Note that the distance L ₁
Is shorter than the distances L ₃ and L ₄ when the end wall portion 22 is welded to the side wall portion 21 rather than the welded portion of the end wall portion 22. First, the side wall 2
This is because consideration is given so that the impact force is transmitted to the welded portion M which is a fragile portion provided in FIG.

Further, the thicknesses t ₁ ,
The thickness t ₃ of the side wall portion 21 is made thinner than t ₂ , so that the welded portion M is considered to be more ruptured.

The electric energy supply device comprises a charger for storing high-voltage electric energy, for example, a discharge circuit for supplying electric energy charged in a capacitor to the pair of electrode rods 13 to cause a discharge. Have been.

By using the above-mentioned electric discharge impact destruction apparatus 1, an object to be destroyed, for example, a concrete plate 2 as shown in FIG.
Is destroyed, the explosive substance 1
After inserting and sealing a pair of electrode rods 13 to which the metal wire 1 and the thin metal wire 14 are connected, the cylindrical container 12 is arranged so that the welded portion M, which is a fragile portion, faces the plate 2,
The electric energy supply device is connected via the electric wiring 15.

Then, by turning on a discharge switch provided in the discharge circuit, the electric energy is quickly supplied to the thin metal wire 1.
4 Then, the thin metal wires 14 are melted and vaporized at a stretch, and the explosive substance 11 filled in the cylindrical container 12 explodes due to the expanding force, that is, the impact force at this time. In this explosion, a part of the explosive substance 11 around the fine metal wire 14 is exploded temporarily due to the impact force generated when the thin metal wire 14 is melted and vaporized. 11 is caused by a secondary explosion.

When the explosive substance 11 explodes, as shown in FIG. 4, the strength of the explosive substance 11 is reduced, and the weld M provided at the position closest to the fine metal wire 14 is ruptured. Since it reliably acts on the plate body 2, FIG.
As shown in (2), the plate body 2 can be efficiently destroyed.

More specifically, the generation pattern of the discharge impact force and the explosion range of the explosive substance spread in a substantially cylindrical shape according to the shape of the thin metal wire 14. That is,
As described above, the cylindrical container 12 is viewed from the side of the thin metal wire 14.
Since the distance to the inner side surface is shorter than the distance from the upper and lower ends of the thin metal wire to the inner surface of the end wall portion, the welding portion of the side wall portion is faster than the peripheral portion of the end wall portion to the side wall portion. M is destroyed, and therefore, it is possible to efficiently apply an impact force to the plate 2 which is the object to be destroyed.

Further, as described above, the explosive substance is used as the substance to be filled in the cylindrical container for destruction, in order to obtain a strong destructive force, and furthermore, the metal cylindrical container is used. The reason for using is to obtain a "reservoir" of explosive power when the explosive substance is detonated.

In the above-described embodiment, the weak portion provided on the cylindrical container 12 has been described as the welded portion M. However, as shown in FIG. 6, for example, as shown in FIG. V-groove-shaped notches 21a formed along the axial direction may be provided on the inner surface of the cylindrical container 12. Further, as shown in FIG. The weak portion may be formed by providing a plurality of holes 21b along the hole. Of course, the hole 21b
It may be of a predetermined depth without penetrating, but if it does not penetrate, it may be provided on either the outer surface or the inner surface. In these cases, the same effects as above can be obtained.
The cylindrical container 12 shown in FIGS. 6 and 7 may be made of a material other than metal, for example, a synthetic resin such as plastic.

In the above description, a thin metal wire is used as the molten vaporized material. However, for example, a thin carbon wire may be used, and the shape of the thin metal wire may be a band, a coil, or a wave. It may be something.

Further, in the above embodiment, a cylindrical container is used as the cylindrical container, but a prismatic container may be used, for example.

In addition to the destruction of a concrete structure, this discharge impact destruction apparatus is capable of moving on a surface (above water) or inside (underwater) of a fluid such as wood, rock or water. , Ships, submersibles) or related facilities [eg, surface facilities, underwater facilities, etc. (of course,
In this case as well, the present invention is not limited to concrete ones.)].

[0029]

As described above, according to the structure of the present invention, the explosive substance is exploded by the impact force generated when the molten vaporized substance is melted and vaporized. At this time, the welded portion, the notch portion, Since a fragile portion such as a hole is provided, by arranging the container so that the fragile portion is located at a position facing the destructible object, the destructible object can be reliably destroyed. By arranging the molten vaporized substance at a position close to the fragile portion and making the thickness of the side wall portion of the container in which the fragile portion is provided thinner than that of the end wall portion, the destructible object is more reliably destroyed. be able to. That is, destruction can be performed efficiently.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a configuration of a discharge impact destruction device according to an embodiment of the present invention.

FIG. 2 is a sectional view taken along line AA of FIG.

FIG. 3 is a cross-sectional view showing a use state of the discharge impact breaking device.

FIG. 4 is a cross-sectional view showing a state at the beginning of the explosion in the discharge impact crushing device.

FIG. 5 is a cross-sectional view showing a destruction state due to an explosion in the discharge impact destruction device.

FIG. 6 is a cross-sectional view showing a modified example of a fragile portion provided in a cylindrical container of the discharge impact breaking device.

FIG. 7 is a front view showing a modified example of a fragile portion provided in a cylindrical container of the discharge impact breaking device.

FIG. 8 is a cross-sectional view showing a usage state of a conventional discharge impact breakdown device.

[Explanation of symbols]

 M Welded part 1 Discharge impact destruction device 2 Concrete plate 11 Explosive substance 12 Cylindrical container 13 Electrode rod 14 Fine metal wire 21 Side wall 21a Notch 21b Hole 22 End wall

Claims (9)

[Claims] An electric energy is supplied in a short time to a molten vaporized substance disposed in a container filled with an explosive substance, thereby rapidly melting and vaporizing the molten vaporized substance. A discharge impact destruction device for destructing an object to be destroyed by detonating the explosive substance, wherein the container is provided with a fragile portion. 2. An electric energy is supplied in a short time to a molten vaporized substance formed in a metal container formed from a side wall and both end walls and filled with an explosive substance to rapidly melt the vaporized substance. A discharge impact destruction device for causing the explosive substance to explode and destroy an object to be destroyed by an impact force generated at the time of melt vaporization and melted and vaporized. Discharge impact destruction device characterized by having provided. 3. A method for supplying electric energy to a molten vaporized substance disposed in a metal or synthetic resin container formed of a side wall and both end walls and filled with an explosive substance in a short time to melt the vaporized substance. A discharge impact destruction device for rapidly melting and vaporizing a vaporized substance and exploding the explosive substance to destroy an object to be destroyed by an impact force generated at the time of the melt vaporization, wherein a notch is formed in a side wall of the container. A discharge impact destruction device characterized by forming: 4. An electric energy is supplied in a short time to a molten vaporized substance formed in a metal or synthetic resin container formed from side walls and both end walls and filled with an explosive substance, thereby melting the molten vaporized substance. A discharge impact destruction device for rapidly melting and vaporizing a vaporized substance and exploding the explosive substance to destroy an object to be destroyed by an impact force generated at the time of the melt vaporization. A discharge impact destruction device comprising a plurality of holes formed along a direction. 5. The discharge impact breakdown device according to claim 2, wherein the molten vaporized material is arranged along a weld provided between the upper and lower end walls. 6. The discharge impact breakdown device according to claim 3, wherein the molten vaporized material is arranged along the notch. 7. The discharge impact breakdown device according to claim 4, wherein the molten vaporized material is arranged along a plurality of holes. 8. A method for forming a molten vaporized substance into a linear shape, wherein the distance between the molten vaporized substance and the side wall of the container is shorter than the shortest distance between the end of the molten vaporized substance and the end wall of the container facing each other. The discharge impact breakdown device according to any one of claims 2 to 7, wherein the molten vaporized material is arranged in the container such that the shortest distance is shorter. 9. The discharge impact breakdown device according to claim 2, wherein the thickness of the side wall portion of the container is smaller than that of each end wall portion.