JP2010261272A - Destruction method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily control the developing direction of crack caused in destruction of an object to be destroyed. <P>SOLUTION: A cartridge 2 of a discharge impact destructive device 1 includes a destruction container 21, a destructive material 22 filled in the container 21 and being combustible under an oxygen-free environment, a pair of electrodes 23 and a metal thin wire 24. In the discharge impact destructive device 1, electric energy is supplied to the electrodes 23 to melt and vaporize the metal thin wire 24, a burning reaction is caused in the material 22 by high temperature of a plasma generated during and after the melting and vaporization to destroy the object by an impact force generated by expansion of the material in the burning. The propagation speed of the burning surface is set to acoustic velocity or less, whereby the material 22 can be burnt without detonation. Consequently, the developing direction of crack can be easily predicted based on the size of a free surface of the object 9 to be destroyed (i.e., the surface where stress is released) or the distance between the cartridge 2 and the free surface to easily control the developing direction of crack. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a destruction method for destroying an object to be destroyed.

  2. Description of the Related Art Conventionally, as a method for destroying an object to be destroyed such as a concrete structure or a rock, a method using an impact force caused by exploding an explosive substance is known. For example, in Patent Document 1, a pair of electrodes connected via a thin metal wire and a destruction container containing nitromethane are inserted into a mounting hole formed in an object to be destroyed, and electric energy is applied to the fine metal wire in a short time. A method is disclosed in which nitromethane is detonated by supplying electric discharge and the material to be destroyed is destroyed by the expansion force when the fine metal wire is melted and vaporized and the explosive force of nitromethane.

  In Patent Document 2, a pair of electrodes connected via a fine metal wire and a destruction container containing water are inserted into a mounting hole formed in the object to be destroyed, and electric energy is applied to the fine metal wire in a short time. In other words, a method is disclosed in which water is rapidly vaporized by supplying electric discharge, and an object to be destroyed is destroyed by expansion during vaporization.

Japanese Patent No. 3672443 Japanese Patent No. 3773305

  By the way, in the method of Patent Document 1, the propagation speed of the combustion surface due to the explosion of nitromethane exceeds the speed of sound and becomes a detonation with a shock wave. The pressure due to drought reaches the peak pressure. Thereby, the site | part surrounding the loading hole with which the explosive was loaded is grind | pulverized, and the crack which arises in a to-be-destructed object by detonation progresses in various directions, Therefore It is difficult to predict the propagation direction of a crack. Further, the method of Patent Document 2 has a limit in improving the destructive force.

  The present invention has been made in view of the above problems, and an object of the present invention is to easily control the propagation direction of a crack that is generated when a to-be-destructed object is destroyed while preventing non-destructive objects from being destroyed more than necessary. It is said.

  The invention according to claim 1 is a destruction method for destroying an object to be destroyed, and a) a recess formed in the object to be destroyed by a material capable of burning in an oxygen-free environment or a low-oxygen environment. And b) a step of positioning a thin metal wire connecting the pair of electrodes inside the destructive substance; and c) supplying electric energy to the pair of electrodes to melt the fine metal wire. The step of causing the destruction material to cause a combustion reaction in which the propagation speed of the reaction surface is equal to or lower than the speed of sound, and destroying the object to be destroyed by expansion during combustion of the destruction material.

  Invention of Claim 2 is the destruction method of Claim 1, Comprising: The said b) process accommodates the said metal fine wire, the said pair of electrode, and the said substance for destruction in a container, and forms a cartridge The step a) is a step of inserting the cartridge into the recess of the object to be destroyed between the step b) and the step c).

  Invention of Claim 3 is the destruction method of Claim 2, Comprising: The said substance for destruction is a liquid.

  The invention according to claim 4 is the destruction method according to claim 3, wherein the destruction material is nitromethane.

  Invention of Claim 5 is the destruction method of Claim 4, Comprising: The impact pressure generated by the melt vaporization of the said metal fine wire is less than 1 GPa (gigapascal).

  In the present invention, it is possible to easily control the propagation direction of a crack generated when the object to be destroyed is destroyed.

It is a figure which shows the structure of a discharge impact destruction apparatus. It is a figure which shows the flow of destruction of the to-be-destructed object by a discharge impact destruction apparatus. It is a figure which shows a discharge impact destruction apparatus and a to-be-destructed object. It is a figure which shows the mode of propagation of a combustion reaction. It is a figure which shows the mode of propagation of a combustion reaction. It is a figure which shows the mode of propagation of a combustion reaction. It is a figure which shows the mode of propagation of a combustion reaction. It is a figure which shows the mode of propagation of a combustion reaction. It is a figure which shows the mode of propagation of a combustion reaction. It is a figure which shows the mode of propagation of a combustion reaction. It is a figure which shows the mode of propagation of a combustion reaction. It is a figure which shows the relationship between the time after reaction start, and an impact pressure.

  FIG. 1 is a diagram showing a configuration of a discharge shock destruction apparatus 1 according to an embodiment of the present invention. As shown in FIG. 1, a discharge impact destruction apparatus 1 includes a cartridge 2 attached to an object to be destroyed such as a concrete structure or rock, a capacitor 4 connected to the cartridge 2 via a wiring 3, and a wiring 5. The wiring 3 and the wiring 5 are provided with a discharge switch 31 and a charging switch 51, respectively. In FIG. 1, a part of the cartridge 2 is drawn in cross section for easy understanding of the drawing.

  The cartridge 2 includes a substantially cylindrical destruction container 21 made of plastic or the like, and a destruction substance 22 (that is, self-reactive property) filled in the destruction container 21 and combustible in an oxygen-free environment or a low-oxygen environment. In this embodiment, nitromethane, which is a liquid, is used.), A pair of electrodes 23 housed in the destruction container 21, and electrodes connected to the tip portions of the pair of electrodes 23 A thin metal wire 24 having a smaller cross-sectional area than 23 is provided. The pair of electrodes 23 are connected to each other through the fine metal wires 24 and are connected to the capacitor 4 through the wiring 3.

  The destruction container 21 includes a container main body 211 having an opening at the top, and a lid portion 212 that closes the opening of the container main body 211 and seals the inside of the container main body 211. The pair of electrodes 23 penetrates the lid part 212 of the destruction container 21 and is fixed to the destruction container 21 by the wiring 3 fixed to the lid part 212, and the electrode 23 and the thin metal wire 24 are destroyed in the destruction container 21. Located inside the working material 22.

  FIG. 2 is a diagram showing a flow of destruction of an object to be destroyed by the discharge impact destruction apparatus 1. When the object to be destroyed is destroyed by the discharge impact destruction apparatus 1, first, as shown in FIG. 3, a recess 91 is formed in the object 9 by a drill or the like (step S11). In the present embodiment, the recess 91 is a deep hole loading hole, and the cross section of the recess 91 perpendicular to the depth direction is substantially circular. In FIG. 3, the destruction target 9 is shown in cross section for easy understanding of the drawing.

  Subsequently, as shown in FIG. 1, the container main body 211 of the destruction container 21 is filled with the destructive substance 22, and a lid 212 to which the electrode 23 and the fine metal wires 24 are fixed is attached to the container main body 211. 23, the fine metal wire 24 and the destructive substance 22 are accommodated in the destructive container 21 (that is, the electrode 23 and the fine metal line 24 are positioned inside the destructive substance 22) to form the cartridge 2 (step S12). . The destruction substance 22 filled in the destruction container 21 is preferably 5 ml (milliliter) or more and 50 ml or less, and in this embodiment, it is 25 ml. A pre-formed cartridge 2 may be prepared.

  When the cartridge 2 is formed, as shown in FIG. 3, the cartridge 2 is connected to the capacitor 4 via the wiring 3 and is inserted into the recess 91 of the destruction target 9, thereby causing the destruction material 22. Is accommodated in the recess 91 (step S13). Next, sand or the like is filled in the concave portion 91 of the object 9 to be destroyed and tamped (so-called tamping is performed), and the charge switch 51 is turned on while the discharge switch 31 of the discharge impact destruction apparatus 1 is turned off. By being turned on, electric energy is accumulated in the capacitor 4 from the DC power source 6.

  Thereafter, the charge switch 51 is turned off and the discharge switch 31 is turned on, whereby the electrical energy accumulated in the capacitor 4 is supplied to the pair of electrodes 23 of the cartridge 2 and the fine metal wires 24 are melted and vaporized. In the present embodiment, electric energy is supplied to the pair of electrodes 23 under conditions where the voltage is 1 kV to 6 kV, the maximum current value is 1 kA to 50 kA, and the supply time is 1 second or less. The melted and vaporized thin metal wire 24 becomes a metal gas of several thousand degrees, and plasma is generated by further supplying electric energy from the capacitor 4 to the metal gas.

  The combustion reaction of the destruction substance 22 starts around the plasma due to the high temperature generated by melting and vaporizing the thin metal wire 24, and the combustion reaction propagates through the destruction substance 22 in the destruction container 21 and spreads. . FIG. A thru | or FIG. H is a view showing a state of propagation of the combustion reaction in the destruction container 21, and a white portion near the center of each drawing shows a combustion portion of the destructive substance 22. FIG. A thru | or FIG. In H, the state from 10 μ (micro) seconds to 80 μ seconds after the start of the combustion reaction is shown every 10 μ seconds. The propagation speed of the reaction surface of the combustion reaction (that is, the combustion surface) inside the destructive substance 22 is equal to or lower than the speed of sound in the standard state of the destructive substance 22 (for example, the state in which the cartridge 2 is filled as a liquid). In this embodiment, the speed per second is about 500 m).

  The impact pressure generated by the vaporization of the fine metal wires 24 is set to 0.05 GPa (gigapascal) or more and less than 7 GPa (more preferably less than 1 GPa). In the discharge impact destruction apparatus 1, the destruction material 22 is caused to undergo a combustion reaction, and the destruction target 9 is destroyed by an impact force (that is, a discharge impact force) generated by the expansion of the destruction material 22 during the combustion (step). S14).

  As described above, in the destruction method described above, the propagation speed of the reaction surface in the combustion reaction of the destruction substance 22 is set to be equal to or lower than the sonic velocity, so that the destruction substance 22 is generated without causing detonation accompanied by a shock wave. The time until the impact pressure due to combustion of the destructive substance 22 reaches the peak pressure can be made longer than that during detonation. In the present embodiment, as shown in FIG. 5, the time from the start of the reaction until the impact pressure reaches the peak pressure is about 250 μsec.

  As a result, the part 9 to be destroyed 9 can be cracked and broken without being crushed (that is, crushed). In other words, the destruction target 9 is prevented from being destroyed more than necessary. Further, the propagation speed of the combustion reaction of the destructive substance 22 is made smaller than the elastic wave velocity of the object 9 to be destroyed (for example, about 3000 m per second when the object 9 is concrete), so that the object 9 Will be in a state close to static destruction. As a result, the crack progresses based on the size of the free surface (that is, the surface where the stress is released and exposed in the air) of the object 9 to be destroyed and the distance between the cartridge 2 and the free surface. It is possible to easily predict the direction, and by adjusting the position of the concave portion 91 into which the cartridge 2 is inserted, the progress direction of a crack generated when the object 9 is destroyed can be easily controlled to obtain a desired destruction mode. Obtainable.

  In the above destructive method, the destructive substance 22 is inserted into the concave portion 91 in a state of being accommodated in the destructive container 21 without being directly filled into the concave portion 91 of the destruction target 9. Therefore, the destruction method is particularly suitable when the destruction substance 22 is a liquid. Further, in the discharge impact destruction apparatus 1, the destruction reaction 22 is made liquid, so that the combustion reaction is uniformly propagated inside the destruction substance 22.

  In the discharge impact destruction apparatus 1, detonation of nitromethane, which is the destruction material 22, can be prevented by setting the impact pressure generated by melting and vaporizing the thin metal wires 24 to be less than 7 GPa. In addition, by setting the impact pressure to less than 1 GPa, detonation of nitromethane can be reliably prevented even when nitromethane contains bubbles or the like. From the viewpoint of obtaining an impact force required for the destruction of the material 9 to be destroyed by burning the destruction material 22, the impact pressure generated by the melt vaporization of the thin metal wire 24 is preferably 0.05 GPa or more. .

  As mentioned above, although embodiment of this invention has been described, this invention is not limited to the said embodiment, A various change is possible.

  For example, the destructive substance 22 is not necessarily limited to nitromethane, and is not limited to a liquid. In the destruction method using the above-described discharge impact destruction apparatus 1, various destruction materials that can be combusted in an oxygen-free environment or a low-oxygen environment (that is, have self-reactivity) may be used.

  Further, in the above-described destruction method, the cartridge 2 is not necessarily used. When the cartridge 2 is not used, instead of Step S12 and Step S13, the step of directly housing the destructive substance 22 in the concave portion 91 formed in the article 9 to be destroyed, and the electrode 23 and the thin metal wire 24 are disposed in the concave portion 91. The step of positioning the inside of the destruction material 22 is performed in this order.

  In the embodiment described above, the recess 91 is a hole formed in the object 9 to be destroyed, but a groove formed in the discharge impact destruction apparatus 1 may be used as the recess 91. Moreover, the above-described discharge impact destruction apparatus 1 can be used for, for example, finishing destruction work in tunnels, concrete structure demolition work, underwater destruction work, and other destruction / demolition work in which blasting work is restricted.

2 Cartridge 9 Destroyed object 21 Destruction container 22 Destructive substance 23 Electrode 24 Metal wire 91 Recess S11-S14 Step

Claims (5)

A destructive method for destroying a destructible object,
a) storing a destructive substance combustible in an oxygen-free environment or a low-oxygen environment in a recess formed in an object to be destroyed;
b) positioning a thin metal wire connecting the pair of electrodes inside the destructive substance;
c) By supplying electric energy to the pair of electrodes to melt the fine metal wires, the destruction material causes a combustion reaction in which the propagation speed of the reaction surface is less than the speed of sound, and the destruction material is burned. Destroying the object to be destroyed by expansion at the time of,
The destruction method characterized by providing. The destruction method according to claim 1,
The step b) is a step of forming a cartridge by accommodating the fine metal wires, the pair of electrodes and the destructive substance in a container,
The destruction method, wherein the step a) is a step of inserting the cartridge into the concave portion of the object to be destroyed between the step b) and the step c). The destruction method according to claim 2,
A destruction method, wherein the destruction substance is a liquid. The destruction method according to claim 3,
A destruction method, wherein the destruction material is nitromethane. The destruction method according to claim 4,
A fracture method, wherein an impact pressure generated by melting and vaporizing the fine metal wire is less than 1 GPa (gigapascal).

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