KR101875748B1 - Method for rock fracture and crack propagation by high voltage shock wave - Google Patents

Abstract

The present invention relates to a rock fracture and crack propagation method using a high-voltage shock wave which excludes the use of explosives and minimizes noise and vibration by applying a high-voltage shock wave in a state where water is filled in a blast hole, A rock breaking and crack propagation method using a high voltage shock wave according to the present invention includes applying a high voltage to water in a rock blast hole in a state where water is filled in a rock blasting hole; A high voltage shock wave is generated due to the application of a high voltage and a strong pressure wave is generated and the water in the rock blast hole is expanded by the pressure wave and crushing and crack propagation of the rock mass is caused by the swollen water .

Description

[0001] The present invention relates to rock breakage and crack propagation by high voltage shock waves,

The present invention relates to a rock breaking and crack propagation method using a high voltage shock wave, and more particularly, to a rock fracture and crack crack propagation method in which a high voltage shock wave is applied in a state where water is filled in a blast hole, And to a rock breaking and crack propagation method using a high voltage shock wave capable of minimizing noise and vibration.

Rock mass excavation works for civil engineering work, resource exploitation work For extraction of rocks aggregate and stone picking work, large and small explosives are mainly used for rock excavation. Rock excavation works in the form of blasting explosive charges on rock blast preforms. In the rock excavation work using such explosives, crushed rocks, noxious gas and dust are discharged by the storm pressure, and there is a problem that it involves strong noise and shock vibration.

Korean Patent No. 164986 discloses a vibrationless and rockeless rock blasting technique, but the use of explosives can not be avoided, so that noise and vibration due to explosive explosion can not be removed.

Korea Patent No. 164986

Disclosure of the Invention The present invention has been devised to solve the above-mentioned problems, and it is an object of the present invention to provide a high-voltage shock wave generator in which a high voltage shock wave is applied in a state where water is filled in a blast hole, And to provide crack cracking and crack propagation methods using high voltage shock waves.

According to another aspect of the present invention, there is provided a rock breakage and crack propagation method using a high voltage shock wave, comprising: applying a high voltage to water in a rock blast hole in a state where water is filled in a rock blast hole; A high voltage shock wave is generated by the application of the high voltage and a pressure wave is generated and the water in the rock blast hole is expanded by the pressure wave and fracture of the rock mass and crack propagation are caused by the expanded water .

The high-voltage application unit may include a power supply unit for supplying an alternating-current power, a transforming unit for transforming the alternating-current power to a high voltage of 1 to 1000 kV, a high-voltage direct- A charging unit for charging the high voltage direct current power source, and an application electrode for discharging the high voltage direct current power source stored in the charging unit, wherein the application electrode is provided in the water-filled rock blast hole.

A first switch is provided between the power supply unit and the transforming unit, a second switch is provided between the rectifying unit and the charging unit, a third switch is provided between the charging unit and the discharging electrode, A fourth switch is provided.

The charging process is performed in a state where the first switch and the second switch are turned on and the third switch and the fourth switch are off, and the AC power source (100 to 300 V) Voltage alternating-current power source (1 to 1000 kV) is generated by the transforming unit, and the transformed high-voltage alternating-current power is rectified to the high-voltage direct-current power by the rectifying unit, and the rectified high-voltage direct-current power is stored in the charging unit.

In the discharging process, the third switch is turned on and the first switch, the second switch and the fourth switch are turned off, and the high voltage DC power stored in the charging unit is discharged through the discharge electrode do. In addition, the first, second, and third switches may be turned off, and the fourth switch may be turned on to completely discharge the DC power remaining in the charging unit through the earth.

In addition, a blast hole sealing member is provided on the rock blasting hole filled with water to prevent water from being discharged to the outside of the blasting hole by underwater high voltage shock waves.

The rock crushing and crack propagation method using the high voltage shock wave according to the present invention has the following effects.

In this method, high pressure is applied to water in a rock blast hole to swell water through strong pressure waves caused by shock waves and to induce crushing and cracking of the rock by the swollen water. First, the pressure wave radially And secondly, it is possible to control the rock breaking and cracking degree according to the control of the applied high voltage magnitude. Third, as the use of explosives is excluded, dust, noise and vibration Can be minimized, and side effects such as external discharge of crushed materials due to the use of explosives can be minimized.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a reference diagram for explaining a rock fracture and a crack propagation technique using a high-voltage shock wave according to an embodiment of the present invention; FIG.
2 is a configuration diagram of a high voltage applying device.
FIG. 3 is a photograph of high voltage applied in water through a rock breaking and crack propagation apparatus using a high voltage shock wave according to an embodiment of the present invention. FIG.
FIG. 4 is a photograph in which a positive electrode electrode (+) and a negative electrode electrode (-) are provided in a rock blasting hole.
FIGS. 5A and 5B are photographs showing the state of a rock blast hole after rock fracture and crack propagation using a high-voltage shock wave according to an embodiment of the present invention. FIG.
6A and 6B are photographs showing a state of a blast hole after a high-voltage shock wave is applied to a granite sample.

The present invention proposes a technique for inducing high voltage shock waves in water to crush rock masses and achieve crack propagation in rock masses.

When a high voltage is applied to water using an electrode rod in a state where water is charged into a rock blast hole, a high voltage shock wave is generated and a pressure wave due to a high voltage shock wave is generated in the water. This pressure wave induces the expansion of the water located in the blast hole, and cracking propagation is caused by the expanded water.

The present invention excludes the use of explosives and induces fracture and crack propagation of rock mass through underwater high voltage shock waves, thereby suppressing noise, dust, and vibration caused by the use of explosives, and preventing discharge of crushed rocks due to storm pressure have.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a rock crushing and crack propagation method using a high voltage shock wave according to an embodiment of the present invention will be described in detail with reference to the drawings.

The rock crushing and crack propagation method using a high voltage shock wave according to an embodiment of the present invention is performed in the following apparatus configuration. Referring to FIG. 1, a plurality of blasting holes 10 having a predetermined size are formed in advance on the rock mass to be shredded. The rock blasting hole 10 is isolated from the external environment and the geometric size of the rock blasting hole 10 can be designed in consideration of the pressure generated by the high voltage shock wave and the voltage application amount for inducing the corresponding pressure.

Water is charged into the rock blast hole 10 and an applied electrode 150 for applying a high voltage, that is, a positive electrode electrode (+) and a negative electrode electrode (-) are disposed in the charged water. A high voltage applying device 100 is provided on one side of the positive electrode bar (+) and the negative electrode bar (-). In addition, a blast hole sealing member 20 is provided on the rock blast hole 10 to prevent the water and the expansion pressure from being released to the outside of the blasting hole 10 by a high-voltage shock wave in the water. The high-voltage applying apparatus 100 can be designed to be charged and discharged, thereby applying a high voltage periodically or intermittently. The detailed configuration of the high-voltage applying apparatus 100 will be described later.

The rock crushing and crack propagation method using the high voltage shock wave according to an embodiment of the present invention will now be described. (+) And a cathode electrode (-) through the high voltage application device 100 in a state where water is filled in the rock blasting hole 10 and the positive electrode electrode (+) and the negative electrode electrode (- -), a high-voltage shock wave is generated in the water in the rock blast hole 10. The high-voltage shock wave generated in the water creates a strong pressure wave, and the water present in the closed rock blast hole 10 is expanded by the pressure wave. As the water present in the closed rock blast hole 10 expands, fracture and crack propagation of the rock are generated.

FIG. 3 is a photograph of a high voltage applied in water through a rock breaking and crack propagation induction apparatus using a high voltage shock wave according to an embodiment of the present invention. It can be confirmed that a high voltage shock wave is generated in the water due to application of a high voltage.

4A and 4B are photographs showing positive electrode electrode (+) and negative electrode electrode (-) in a rock blast hole, FIGS. 5A and 5B are photographs of a rock subjected to rock fracture and crack propagation using a high voltage shock wave according to an embodiment of the present invention, This is a photograph of the condition of the blast hole. 5A and 5B, it can be seen that a large number of cracks are generated inside the rock blasting hole and around the rock blasting hole after the rock breaking and crack propagation using the high voltage shock wave.

Rock fracture and crack propagation method using high voltage shock wave according to the present invention was performed on granite samples. The experimental method is as follows. A granite sample of 200 mm x 200 mm x 300 mm in width x length x height was prepared and a blast hole having a diameter of 80 mm and a depth of 250 mm was formed at the center of the granite sample. The blasting hole of the granite sample was filled with water, the copper electrode rod was inserted into the blasting hole, and the blasting hole was sealed. Two identical granite samples of the above conditions were prepared. Then, a high voltage was applied to the copper electrode inserted into each granite sample at a different arbitrary value.

As a result of examining the state of two granite samples after the high voltage was applied and the water was drained out, two large cracks were generated in the granite samples with low voltage applied inside and around the blast holes (see FIG. 6A) It was confirmed that about 7 large cracks were generated inside and around the blasting hole (see FIG. 6B).

These results show that the pressure wave generated by the underwater high voltage shock wave is transmitted to the blast hole relatively uniformly, effectively inducing the crack of the blast hole. By controlling the high voltage according to the type of rock, .

Meanwhile, a high-voltage applying device for applying a high voltage to the water charged in the rock blasting hole may be designed in various forms. In one embodiment, the high-voltage applying device may be designed as follows.

2, a high voltage applying apparatus 100 according to an exemplary embodiment of the present invention includes a power supply unit 110, a transformer unit 120, a rectifier unit 130, a charger unit 140, and an application electrode 150 . The power supply unit 110 supplies AC power of 100 to 300 V and the transformer unit 120 transforms the AC power input through the power supply unit 110 to a high voltage of 1 to 1000 kV.

The rectifying unit 130 rectifies the high voltage AC power source transformed by the transforming unit 120 to a high voltage DC power source and the charging unit 140 rectifies the high voltage DC power source, which is rectified by the rectifying unit 130, It plays a role of saving. In this case, the rectifying unit 130 may be configured by disposing a plurality of diodes in a circulating high-voltage cable, and the charging unit 140 may be configured by connecting a plurality of capacitors in parallel. A resistor is disposed in a line between the rectifying part 130 and the charging part 140 for current flow.

The applied electrode 150 is connected to both ends of the charging unit 140 to discharge the high voltage charged in the charging unit 140 to water present in the rock blasting hole 10. The applied electrode 150 corresponds to the positive electrode electrode (+) and the negative electrode electrode (-).

In the present invention, high voltage charging and discharging can be selectively performed. To this end, the high voltage applying apparatus 100 is provided with four switches, that is, first to fourth switches 101, 102, 103, 104 . The first switch 101 is provided between the power supply unit 110 and the transforming unit 120 and the second switch 102 is provided between the rectifying unit 130 and the charging unit 140. The third switch 103, Is provided between the charging unit 140 and the application electrode 150. [ The fourth switch 104 is connected to the charging unit 140 and the earth and the ground is branched between the charging unit 140 and the applying electrode 150.

Under such a configuration, the selective charging and discharging operation of the high voltage will be described as follows. First, the charging process proceeds while the first switch 101 and the second switch 102 are turned on and the third switch 103 and the fourth switch 104 are turned off. The AC power source 100 to 300V is supplied from the power supply unit 110 to the transformer unit 120 in response to the ON state of the first switch 101 and the second switch 102, Voltage DC power source is rectified by the rectifying unit 130 to a high-voltage DC power source, and the rectified high-voltage DC power is supplied to the charging unit 140 through a capacitor do.

Next, the discharging process proceeds while the third switch 103 is turned on and the first switch 101, the second switch 102, and the fourth switch 104 are off. That is, the discharging process is performed in a state where only the charging unit 140 and the applying electrode 150 are electrically connected, and the high-voltage DC power (1 to 1000 kV) accumulated in the charging unit 140 is transferred Is applied to the water in the blast hole (10).

When a high voltage is applied to the water in the rock blast hole 10 through the applied electrode 150, that is, the positive electrode bar (+) and the negative electrode bar (-), generation of high voltage shock waves, generation of pressure waves, The water is expanded, the rock is fractured by the expanded water, and crack propagation progresses sequentially.

When the discharging process is completed, the charging process is performed again. It is necessary to completely discharge the DC power remaining in the charging unit 140 to the outside before proceeding with the charging process. This is for maintaining and maintaining a constant high voltage stored in the charger 140. The first, second and third switches 103 are turned off and the fourth switch 104 is turned on to completely discharge the DC power remaining in the charging unit 140, The residual power of the charging unit 140 is completely discharged through the earth.

10: rock blasting hole 20: blasting hole sealing member
100: high voltage applying device 101: first switch
102: second switch 103: third switch
104: fourth switch 110: power supply unit
120: Transformer 130:
140: Charging part 150:

Claims (7)

Applying a high voltage to the water in the rock blast hole in the state that the rock blast hole is filled with water;
A high voltage shock wave is generated by the application of a high voltage and a pressure wave is generated and the water in the rock blast hole is expanded by the pressure wave and fracture and crack propagation is caused by the expanded water,
Wherein the high voltage is applied by a high voltage applying device,
A transformer for transforming the AC power to a high voltage of 1 to 1000 kV; a rectifying unit for rectifying the transformed AC power to a high-voltage DC power source; a charging unit for charging the high-voltage DC power source; And an application electrode for discharging the high-voltage DC power stored in the charging unit,
The applied electrode is provided in a water-filled rock blasting hole,
A first switch is provided between the power supply unit and the transforming unit, a second switch is provided between the rectifying unit and the charging unit, a third switch is provided between the charging unit and the discharging electrode, A fourth switch is provided in the second switch,
The charging process,
The first switch and the second switch are turned on and the third switch and the fourth switch are turned off and the AC power source (100 to 300V) is supplied from the power supply unit to the transforming unit, Voltage alternating-current power source (1 to 1000 kV) is generated by the rectifying unit, the rectified high-voltage alternating-current power is rectified to the high-voltage direct-current power source, the rectified high-
In the discharge process,
The third switch is turned on and the first switch, the second switch and the fourth switch are turned off, and the high voltage DC power stored in the charging unit is discharged through the discharge electrode Rock Breaking and Crack Propagation Method Using High Voltage Shock Wave.
delete delete delete delete 2. The method of claim 1, wherein the first, second, and third switches are off and the fourth switch is on,
And discharging the DC power source remaining in the charging unit through the earth, wherein the high voltage shock wave is used for crushing and crack propagation.
The rock breaking and crack propagation method according to claim 1, further comprising a blasting hole sealing member for preventing water from being discharged to the outside of the blasting hole by a high-voltage shock wave in the water on the rock blasting hole filled with water .

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