JPH11257899A - Destroying method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently destroy an object by an impact force and explosion force of a destroying substance by exploding the destroying substance by the impact generated when a fused gasifying substance is fused and gasified. SOLUTION: The destroying method is such that a charge energy charged in a capacitor is fed for a short time to a thin metal wire 2 to rapidly fuse and gasify the thin metal wire 2, thus exploding all nitromethane by resultant impact wherein it is exploded only when an electric energy for fusing and gasifying the thin metal wire 2 is given, and hence a destroying apparatus can be handled safely.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for melting and vaporizing a molten vaporized substance (for example, a fine metal wire) by supplying electric energy in a short time, and using the phenomenon of the process accompanying the molten vaporization to explosive (or combustible). The present invention relates to a destruction method for exploding a destructive substance of the type described above to destroy an object to be destroyed, such as a concrete structure or a rock.

[0002]

2. Description of the Related Art Conventionally, in order to destroy an object to be destroyed such as a concrete structure or a bedrock, there is a method using a dynamite and a primer as a means for exploding the dynamite.

[0003] By the way, dynamite is constructed so that it does not easily explode even if a slight impact force is applied by using an insensitive explosive or a flash fire in order to ensure safety. For this reason, the detonator is filled with explosive which explodes easily, and the explosive is exploded by fire or electric spark, and the explosive explodes the explosive on the dynamite side.

[0004]

As described above, the primer is loaded with explosive which explodes relatively easily.
When a leakage current, surge, lightning, or the like of a peripheral device occurs, there is a danger that these currents are supplied to the primer and explode.

Therefore, an object of the present invention is to provide a destruction method capable of solving the above-mentioned problems.

[0006]

Means for solving the problem of the present invention is to provide a method for rapidly charging a molten vaporized material by supplying charging energy charged to a capacitor to the molten vaporized material in a short time. When the explosive destructive substance provided around the molten vaporized substance is exploded by the impact force generated due to the melt vaporization of the molten vaporized substance and the object to be destroyed is destroyed, The relationship between the longest distance L _c to the end of the substance, the charging energy W _c , and the impact force F of the molten vaporized substance required to explode the destructive substance is expressed by the following equation (a): L _c ≦ 8 · W _c / F (a) is set to satisfy.

According to this destruction method, the destructive substance explodes due to the impact force when the molten vaporized substance is melted and vaporized, and the object to be destroyed can be efficiently destroyed by the impact force and the explosive force of the destructive substance. Even if leakage current of peripheral equipment occurs, the destructive substance does not explode unless electric energy enough to melt and vaporize the molten vaporized substance is used, so the safety in handling the equipment is significantly improved,
By setting as in the above equation (a), all the destructive substances can be exploded by a single impact, and no destructive substances remain.

[0008]

Embodiments of the present invention will be described below with reference to the drawings. First, a destruction apparatus 1 for performing a destruction method according to the first embodiment of the present invention will be described.

As shown in FIG. 1 to FIG.
Is provided with a destruction probe P to be mounted in the mounting hole 5 formed in the object 4 to be destroyed. The destruction probe P is made of a thin metal material such as aluminum or iron, or a wood material other than a metal material, a paper material, or a synthetic material. Breaking container 6 formed of resin material
The explosive destructive substance 7 enclosed in the destruction container 6, a pair of electrodes 9 inserted through a lid member 8 attached to the destruction container 6, and the tips of these electrodes 9 are connected. And a thin metal wire (one example of a molten vaporized material, which is made of Cu or the like) 2, and nitromethane, for example, is used as the breaking material 7.

An electric energy supply circuit 10 for supplying a predetermined amount of electric energy required for melting and vaporizing the thin metal wire 2 is connected to the electrode 9.
The electric energy supply circuit 10 includes a terminal 8 of each electrode 9.
a and a capacitor 14 connected in series between the power supply 11 and one terminal 8a and connected in parallel between the power supply 11 and both terminals 8a. It comprises a charge control circuit 12 for controlling to store electric energy, and a discharge switch 13 connected between the charge control circuit 12 and one terminal 8a.

Next, the object 4 to be destroyed is
The destruction method when destroying is described. First, destruction vessel 6
A breaking substance 7 is put into the container, and an electrode 9 having the ends connected by a thin metal wire 2 is inserted into the cover member 8, and the cover member 8 is connected to the breaking container 6.
To produce a destructive probe P. Then, the breaking probe P is mounted in the mounting hole 5 formed in the object 4 to be broken, and the electric energy supply circuit 10 is connected to the electrode 9.

The charging energy charged in the capacitor 14 of the electric energy supply circuit 10 is transferred to the thin metal wire 2.
Supply in a short time (μS order)
The metal wire 2 is rapidly melted and vaporized, and the impact force due to the discharge energy and the volume expansion energy when the metal wire 2 is melted and vaporized (a phenomenon associated with the process of melting and vaporizing the metal wire 2. Discharge, sparks, heat)
Then, the destructive substance 7 provided around the thin metal wire 2 is exploded, and the object to be destroyed 4 is destroyed by the expansion force when the thin metal wire 2 melts and evaporates and the explosive force of the destructive substance 7.

By the way, an example of assembling the destruction probe P when the destruction substance 7 is put in the destruction container 6 and the lid member 8 is attached to the destruction container 6 may be as shown in FIGS.
When manufacturing the breaking probe P, the longest distance L _c (cm) from the fine metal wire 2 to the end of the breaking substance 7 is known. In each figure, the longest distance L among Lt1, Lt2, Ls1, and Ls2 is shown.
_c is Ls2 in FIG. 3, Lt1 in FIG. 4, and Ls1 in FIG.

When the object 4 is to be destroyed, the longest distance L _c from the thin metal wire 2 to the end of the substance 7 for destruction, the charging energy W _c (Joule) for the capacitor 14, and the destruction of the substance for destruction 7 are exploded. Explosion conditions required to make
There the relationship impact force) P _b generated upon melting vaporized ^{(kg · f / cm 2)} , the (a) (b) below formula corresponding to formula _{L c ≦ 8 · W c /} P b (b ) Is set to satisfy.

Here, the charging energy W of the above equation (b)
_c is based on the following equation (c). W _c = (１ ／) · C · V _c ² (c) In the above equation (c), C: capacitor capacity (F) and V _c : capacitor charging voltage (V).

[0016] Then, the explosion conditions P _b of destruction for the substance 7,
Since determined by breaking substance 7 to be used, the equation (b) charging energy W _c so as to satisfy, i.e. to determine the condenser capacity C, and the capacitor charge voltage V _c, was charged in an amount necessary to condenser 14 Then, the discharge switch 13 is turned on, and charging energy is supplied from the capacitor 14 to the thin metal wire 2 in a short time.

[0017] Then, the metal thin wire 2 is rapidly melted vaporized, explosion condition P _b acts on the breaking substance 7, as described above L _c
Since the set _{≦ 8 · W c / P b} , all the destructive material 7 is completely explosion, this explosive force, the debris 4 is weakened or destroyed.

FIGS. 6 and 7 show patterns of generation of the impact force F when the thin metal wire 2 is melted and vaporized. A portion A shown by a solid line in the drawing is a range in which an explosion occurs due to the impact force F acting.

FIG. 8 shows the relationship between the distance L away from the metal wire 2 and the impact force F. From this graph, it can be seen that the impact force F is almost inversely proportional to the distance L away from the metal wire 2.

Further, FIG. 9 is a graph showing the relationship between the impact force F and the charging energy W _c at a position away 1cm from the fine metal wire 2, that the impact force F and the charging energy W _c is proportional to I understand. That is, when the impact force F caused by the charged energy W _c, 1c from the fine metal wire 2
The impact force F at a distance of m is shown in FIG.
Formula: F = 8 · W _c (d)

From this equation (d), the distance L from the fine metal wire 2 is obtained.
The impact force F at a position distant by the distance is represented by the following equation (e): F = 8 · W _c / L (e)

The coefficient [8] is an average value obtained from an experiment, and the value varies in the range of [6 to 10]. From the above equations (d) and (e), when the impact force F when the thin metal wire 2 melts and vaporizes is the explosion condition _Pb , the range of the destructive substance 7 that explodes under the explosion condition _Pb is shown in FIG. When 6 and the distance from the metal thin wires 2 shown in FIG. 7 (hereinafter referred to as "explosive radius") and L _b, these relationships, the following (f) formula _{L b = 8 · W c /} P b (f) .

In the destruction method according to the embodiment of the present invention, as shown in the above equation (b), L _c ≦ 8 · W _c / P
_b, it is determined that L _c ≦ L _b from the relationship with the above equation (f), and if the impact force F when the thin metal wire 2 is melted and vaporized is under the explosion condition P _b , destruction occurs. all explosion conditions P _b of use substances 7 to work the explosion.

Next, a specific example using nitromethane as the destructive substance 7 will be described with reference to FIG. 90 cc (about 100 g) of nitromethane is filled in a breaking vessel 6 having an inner diameter of 40 mm, and a thin metal wire 2 is arranged in the center of the breaking vessel 6.
_It was immersed in nitromethane with _c = 2 cm.

[0025] explosion conditions P _b of nitromethane is about 70000kg ·
Since f / cm ² (70ton · f / cm ² ), from the above formula (f),
Charging energy W _c needed to detonate all nitromethane is required than 17500Joule. Therefore, the capacitor capacity is set to 500 μF and the charging energy W _c : 20250Jo
ule (capacitor charging voltage V _c: 9000V) was discharged as. As a result, it was confirmed that all the nitromethane in the destruction container 6 exploded, and the same destructive power as that obtained when 100 g of tithamite was used was obtained.

FIG. 10 is a graph showing the relationship between the current Id discharged to the thin metal wire 2, the generated impact force F, and the time t. The thin metal wire 2 connects the electrodes 9. The short circuit between them causes a transient current determined by the circuit impedance indicated by the two-dot chain line in FIG. However, when electric energy for melting and evaporating the thin metal wire 2 is supplied, the thin metal wire 2 is cut off and the circuit is cut off, so that the current Id is shown by a solid line.
FIG. 11 shows that the impact force F occurs when the thin metal wire 2 is broken.

In the embodiment of the present invention, the destruction container 6 is filled with an explosive destructive substance 7, and the thin metal wire 2 connected to the electrode 9 is used instead of the primer. Even if a leakage current or the like of the device occurs, the thin metal wire 2 is not cut off unless electric energy enough to melt and vaporize the thin metal wire 2 is supplied, so that the substance 7 for destruction does not explode. 1 can be handled safely and can be safely destroyed.

According to the impact force F generated by melting and vaporizing the thin metal wire 2, conventionally,
Unless a large impact force (about 70,000 kg · f / cm ² or more is required and explosives were exploded to obtain that impact force), nitromethane that was not used because it did not explode can be used, In this case, an explosive power equivalent to that of titanite is obtained, and the destructible object 4 can be reliably destroyed or weakened.

Further, the dynamite which has been used in the prior art is used by destroying the object to be destroyed 4 with a destructive force as required each time, so that the dynamite has poor responsiveness to the situation at the site and requires In some cases, dynamite having the above destructive power must be used, which is uneconomical. However, according to the destruction apparatus and the destruction method of the embodiment of the present invention, the destructive , The responsiveness to the situation at the site is improved, and there are many cases where it is economically advantageous as compared with the case where dynamite is used.

In the above-described embodiment, nitromethane is shown as an example of the explosive destructive substance 7. However, the present invention is not limited to this. For example, it is described in “Chemical Handbook” edited by “The Chemical Society of Japan”. An explosive compound, methyl nitrate, a nitro compound, or the like may be used. In this case, too, the charging energy _Wc is adjusted so as to generate an impact force corresponding to each substance, and the thin metal wire 2 is melted and vaporized. Thereby, all the destructive substances 7 explode by the impact force, and the destructible object 4 can be surely destroyed or weakened, and even if a leakage current of the peripheral device is generated, the thin metal wire 2 can be formed. Unless electric energy enough to melt and vaporize is supplied, the substance for destruction 7 does not explode, so that it can be handled with safety.

In the above embodiment, the thin metal wire 2 is used as an example of the molten vaporized material. However, the present invention is not limited to this. For example, a small metal piece or a conductive material such as carbon may be used. A material formed in an appropriate shape may be used. In this case, too, electric energy is supplied to the melted vaporized material to cause it to melt and vaporize, and the explosive destructive substance 7 is exploded by the impact force F at that time. Thereby, the object to be destroyed 4 can be reliably destroyed or weakened.

Further, in the above embodiment, the destruction container 6 is used so as to be mounted in the mounting hole 5 formed in the object 4 to be destroyed. However, the present invention is not limited to this. It may be applied to the surface of the object 4 or it may be used by suspending it with an appropriate hanging tool and arranging it near the surface of the object 4 to be destroyed. It can be effective.

In the above embodiment, the destructive probe P is manufactured and mounted in the mounting hole 5.
Without being limited to this, the material 7 for direct destruction is filled into the mounting hole 5 without using the destruction container 6, and the molten vaporized material such as the fine metal wire 2 is immersed in the material 7 for destruction. A predetermined electric energy may be supplied to the vaporized substance to explode the destruction substance 7, and in this case, similarly to the above embodiment, the object 4 can be safely destroyed.

Further, by adjusting the destruction force of the destruction device of the above embodiment, the destruction device can be used as a hypocenter device for geophysical exploration.

[0035]

As is apparent from the above description, the present invention supplies charging energy in a short time to rapidly melt and vaporize the molten vaporized material, and the impact force generated at that time causes the surrounding of the molten vaporized material to be melted. Explosion of the destructive substance destroys the object to be destroyed, so the destructive substance does not explode unless electric energy is supplied enough to melt and vaporize the molten vaporized substance, thus significantly improving safety when handling the equipment. The relationship between the longest distance L _c from the molten vaporized substance to the end of the destructive substance, the charging energy W _c , and the impact force F of the molten vaporized substance required to explode the destructive substance is represented by L _c By setting to satisfy ≦ 8 · W _c / F, all destructive substances explode with one impact,
No destructive material remains.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view illustrating a configuration of a destruction probe according to an embodiment of the present invention.

FIG. 2 is an overall schematic configuration diagram showing the entire destruction device.

FIG. 3 is a partial cross-sectional view showing an example of the arrangement of thin metal wires in the destruction probe.

FIG. 4 is a partial sectional view showing another example of the arrangement of the thin metal wires in the destruction probe.

FIG. 5 is a partial cross-sectional view showing another example of the arrangement of the thin metal wires in the destruction probe.

FIG. 6 is a front view showing a generation pattern of an impact force when the thin metal wire is melted and vaporized.

FIG. 7 is a plan view showing a generation pattern of an impact force when the thin metal wire is melted and vaporized.

FIG. 8 is a graph showing a relationship between an impact force when the thin metal wire is melted and vaporized and a distance away from the thin metal wire.

FIG. 9 is a graph showing the relationship between the impact force when the thin metal wire melts and evaporates and the charging energy to the capacitor.

FIG. 10 is a graph showing a relationship between a current discharged to a thin metal wire, a generated impact force, and time.

FIG. 11 is a graph showing a relationship between impact force and charging energy generated after the thin metal wire is broken.

[Explanation of symbols]

Breaking substance from 1 destructor 2 thin metal wire 4 the disrupter 5 mounting holes 6 destroyed container 7 destruction substance 9 electrode 10 electric energy supply circuit 11 power supply 12 charging control circuit 13 discharge switch 14 Condenser P destruction probe L _c thin metal wire Longest distance to the edge of

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Kazuya Sasaki 1-7-89 Minami Kohoku, Suminoe-ku, Osaka-shi, Osaka Inside Hitachi Zosen Corporation (72) Inventor Tetsuya Inoue 1 Minami-Kohoku, Suminoe-ku, Osaka-shi, Osaka Hitachi Shipbuilding Co., Ltd.

Claims (1)

[Claims] 1. By supplying charging energy charged to a condenser to a molten vaporized substance in a short time,
When the molten vaporized material is rapidly melted and vaporized, and the explosive destructive substance provided around the molten vaporized material is exploded by the impact force generated by the melt vaporization of the molten vaporized material to destroy the object to be destroyed. the maximum distance L _c to the end of the disruption agent from the molten vapors, charge energy W _c, the relationship between the impact force F of the molten vapors needed to detonate the destruction substance, the following equation (a) A destruction method characterized by setting _Lc ≦ 8 · _Wc / F (a).