KR19980050029U - Electrode bar for electric wire type plasma wave - Google Patents

Abstract

The present invention is simple to manufacture and can be produced at a relatively low cost, and relates to an electrode rod for wire-type plasma rock can absorb the resilience. The electrode rod has a negative electrode cable connected to a brass rod connected to the negative electrode of the power supply at one end, and a plate shape connected to the other end of the negative electrode cable, and a negative electrode piece supplied with a negative current from the power supply through the negative electrode cable; And an anode cable having a plate shape connected to the other end of the anode cable and a cathode cable connected to a cathode rod connected to the anode of the power supply at one end thereof, and including an anode piece supplied with anode current from the power supply through the anode cable. do. On the other hand, the electrode pieces can be fixed to face in parallel by the electrode piece holder.

Description

Electrode bar for electric wire type plasma wave

TECHNICAL FIELD The present invention relates to a plasma electrode, and more particularly, an electrode rod for efficiently crushing rock and rock during formation of a closed tunnel, rock collection of a quarry, land development, underground excavation, and construction of a large structure. The present invention relates to an electrode rod for electric wire type plasma rock.

Conventionally, powder blasting has been used in the rock and rock crushing operation. However, when using such chemicals, there is a great risk of a safety accident due to severe vibration and noise, toxic gas, dust, etc. during blasting. In particular, in areas with dense populations and buildings close to homes and shopping malls, complaints were generated, and the place of use was severely restricted, and the use of gunpowder was regulated by the law.

In addition, in the rock and rock crushing operation, the use of these chemicals is expensive for material, labor, and civil complaints, and it is difficult to easily control the blast energy according to the rock and rock conditions, and to automate the blasting work. In addition, the energy use efficiency (about 10%) was extremely low.

Even in the case of using a crusher of another breaker or jaw crusher, since the weight of the tool is large, it is difficult to handle and work at the crushing position. Exposed.

On the other hand, in order to solve the problems caused by the rock crushing method as described above has been proposed a method of crushing the rock using electric energy, more specifically, a plasma blasting device consisting of a power supply, a switch, a blasting electrode rod is used It is made by drilling a hole in the rock, inserting an electrode rod equipped with an electrolytic material in the hole, and then discharging the electrical energy to the electrode in a short time through a large power switch, thereby converting the electrolytic material into a high temperature and high pressure plasma, The shock wave obtained at this time is used for crushing rock.

Such a plasma rocking method uses the principle that the negative charge of a lightning strikes the positive charge of a tree or a rock, and the wood or rock is destroyed by a lightning strike, and there is no toxic harmful gas generation and no scattering of debris during rock destruction. Blasting sound is also about 120db at a distance of 3m, there is a work environment, there is no risk of a safety accident, easy handling and continuous work has the advantage that can improve the workability of rock.

However, the conventional electrode for the rock is to form the outer diameter of the electrode almost coincide with the hole formed in the rock to take a forced fit, it requires a strong pressure from the outside when the electrode is inserted, thereby causing damage to the electrode In addition, a separate insertion tool is required, and the electrode is rebounded and bounces due to the rock pressure generated during rocking, which may shorten the lifespan of the electrode and cause injury.

Patent Application No. 94-28815, filed November 4, 1994, filed by the present applicant under the name of plasma rock electrode, is provided with a gap between the hole and the electrode during opening to solve the above problems. In addition to forming a tubular secondary electrode that prevents), a plasma wave electrode is provided with a heavy electrode support plate coupled to the upper end of the external electrode to prevent the electrode from protruding in the reverse direction by reaction force during the rock. .

Referring to FIGS. 1 and 2, in detail, the center electrode 21 and the center electrode connected to the power supply unit 25 through a cable 20 from an external power supply unit 25 to receive electric energy. Unnecessary discharge between the electrode rod E which has the external electrode 23 formed in the outer side of the 21, and is connected with the power supply part 25 through the cable 31, and the center electrode 21 and the external electrode 23. As shown in FIG. An insulator 22 for blocking the insulation, and an electrolytic material 24 embedded with the electrode at the lower end of the rock 30 to react with the discharge to provide a rock force.

The external electrode 23 induces shape maintenance and discharge of the electrode. The secondary electrode 26 made of the tubular body 26A is detachably installed at the lower end of the external electrode 23 to prevent leakage of pressure generated when rocking outward and to discharge in association with the central electrode 21. . The upper end of the tubular body 26A forms an annular recessed groove 26B so as to reduce the resistance to deformation of the tubular body 26A shape during rocking. On the other hand, the electrode support plate 27 inserted and supported in a detachable state on the upper end of the external electrode 23 suppresses the reverberation of the electrode rod E during rocking.

In addition, Patent Application No. 96-9448 filed on March 30, 1996, filed under the name of the electrode for plasma rock, by the present applicant has a structure as shown in FIG.

In the above-described electrode for plasma rock, the electrode tip 45 formed with a plurality of first openings 47 is formed in order to prevent the rock pressure from leaking due to leakage of the rock pressure. ) Is installed at the end. The electrode tip 45 receives the center electrode 43, and is provided with an electrolytic material (not shown) at the end portion of the electrode 41. Also, by filling the sand for preventing the shot at the space between the hole formed in the rock and the external electrode 42, the reaction force generated at the time of blasting is absorbed by the sand to prevent the ball impact.

On the other hand, the electrode for plasma rock, as well as the wire connected to the electrode is broken by the elastic force generated at the time of blasting and can not be used again, the plasma electrode used for the rock has a simple structure and is manufactured at low cost It is preferable.

However, the conventional electrodes as described above have a problem that the manufacturing cost becomes expensive because they have a relatively complicated structure, as described in the specification and shown in the drawings.

In addition, the electrodes for the plasma rock as described above should be provided with a support on the top of the electrode or to provide a heavy load of weight in order to prevent the electrode from bouncing upward during the plasma rock, the structure and installation is complicated problem There was this. In addition, since the conventional electrodes have a relatively complicated structure, when the rocking force is operated, the elastic force generated in the hole is applied to the electrode as a whole, so that the electrode may be shot and cause an accident.

Accordingly, an object of the present invention is to provide a wire-type plasma wave electrode electrode that can be manufactured at a relatively low cost because the production is simple, and can absorb the resilience.

1 is a view schematically showing an example of use of a conventional electrode for plasma rock.

2 is a cross-sectional view showing the configuration of the electrode for plasma rock used in FIG.

3 is a cross-sectional view showing another conventional electrode for plasma rock.

Figure 4 is a perspective view schematically showing an electrode for a wire type plasma rock electrode according to an embodiment of the present invention.

Figure 5 is an exploded perspective view schematically showing an electrode rod for the wire-type plasma rock coupled to the electrode piece holder according to a modification of the present invention.

FIG. 6 is a perspective view showing a state in which the electrode piece holder shown in FIG. 5 is coupled; FIG.

* Description of the symbols for the main parts of the drawings *

1: negative cable 2: positive cable

3, 4 brass bar 5: anode piece

6: cathode piece 7: electrode piece holder

8a, 8b: Parallel groove 9: Bolt

10: bolt fastener

The object as described above, the negative electrode cable is connected to a brass rod connected to the negative end of the power supply at one end; A cathode piece having a plate shape connected to the other end of the cathode cable and supplied with a cathode current from a power supply through a cathode cable; An anode cable connected to one end of a brass rod connected to an anode of a power supply unit; It is achieved by a wire-type plasma rock electrode according to the present invention, characterized in that it has a plate shape connected to the other end of the positive electrode cable and includes a positive electrode piece to which positive current is supplied from the power supply through the positive cable. .

Alternatively, the electrode pieces may be fixed to face in parallel by an electrode piece holder.

According to the wire type plasma rock electrode according to the present invention as described above, the electrode for plasma rock can be manufactured inexpensively, the rock force generated during the plasma rock is absorbed in the sand filled in the hole and transmitted to the electrode This prevents the need for a support or a heavy load weight to be installed or provided on top of the electrode to prevent the electrode from bouncing upwards.

EXAMPLE

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is a perspective view schematically showing an electrode for a wire-type plasma rock electrode according to an embodiment of the present invention. As shown in Figure 4, the wire-type plasma electrode rod according to the present invention consists of two cables (1, 2). These cables are connected to the negative electrode cable (1) connected to the negative electrode of the power supply (not shown) at one end and the brass bar (4) connected to the positive end of the power supply at one end is connected. Positive cable (2).

The other end of the negative electrode cable 1 is provided with a negative electrode piece 6 having a plate shape, and the negative electrode cable 6 is supplied with a negative current from the power supply through the negative electrode cable 1. The other end of the positive cable 2 is provided with a positive electrode piece 5 having the same shape as the negative electrode piece 6, and the positive electrode piece 5 is supplied with a positive current from the power supply through the positive cable 2. . The positive electrode piece 5 and the negative electrode piece 6 are made of copper so that electricity is well communicated.

When the use of the electrode bar according to the present invention as described above will be described, the cathode piece 6 and the cathode piece is filled with a predetermined amount of the electrolytic material in the hole perforated in the rock slightly larger than the width of the anode piece 5, (6) and the positive electrode piece 5 is inserted into the hole in which the rock is formed in a state facing in parallel with each other. At this time, it is preferable that the cathode piece 6 and the anode piece 5 are completely accommodated in the electrolytic material, and the cathode piece 6 and the anode piece 5 are located above the points connected to the cables 1 and 2. The remaining space of the hole in which it is located is filled with an anti-carbon material such as sand.

The electrolytic material used together with the electrode for plasma rock cancer according to the present invention is not only excellent in its own plasma efficiency, but also can reduce the discharge loss, thereby minimizing the loss of plasma rock energy. Meanwhile, the electrolytic material used in the present invention is a composition in which aluminum powder, water, and copper oxide powder are mixed at an appropriate ratio, and shows no chemical reaction at room temperature, but aluminum powder is water at high temperature and high pressure for plasma generation. Coupled with oxygen in copper oxide with high affinity, exothermic reaction occurs during the reaction, and enormous volumetric energy is accompanied with the generation of hydrogen gas, and enormous chemical energy is generated as shock waves of high temperature and high pressure. Therefore, it contributes greatly to the discharge and plasma formation of the electrode according to the electric energy by the power supply.

The negative electrode piece 6 and the positive electrode piece 5 are inserted into the electrolytic material filled in the holes formed in the rock, and the negative electrode piece 6 and the positive electrode piece 5 are positioned above the points connected to the cables 1 and 2. When the space is filled with an anti-carbon material such as sand, the external power supply unit for supplying current to the cathode piece 6 and the anode piece 5 through the cables 1 and 2 is turned on. Electrical energy is supplied to the cathode piece 6 and the anode piece 5 through 2). Therefore, a strong discharge phenomenon is generated from the positive electrode piece 5 having a positive polarity to the negative electrode piece 6 having a positive polarity, and the plasma is instantaneously discharged from the cathode piece 6 and the electrolyte material filled around the anode piece 5. The rock is crushed by kinetic energy, ie, high temperature and high pressure shock waves, due to the volume expansion of the plasmalized electrolytic material.

At this time, the resilience force that the electrode sticks out of the hole by the reaction force due to the rocking force at the time of rocking is filled with sand filled in the space above the point where the cathode piece 6, anode piece 5 and cable 1, 2 are connected. Since the cathode pieces 6 and the anode pieces 5 have a structure in which the elastic force is not transmitted, the worker's injury due to the elastic force generated at the time of rocking can be prevented. .

FIG. 5 is an exploded perspective view schematically illustrating an electrode rod for a wire type plasma wave cancer coupled by an electrode piece holder according to a modified example of the present invention, and FIG. 6 is a state in which the electrode piece holder shown in FIG. 5 is coupled. One perspective view.

As described above, the electrode rod for the wire-type plasma wave rock according to the present invention is preferably inserted into the hole punched in the rock in the form in which the anode piece 5 and the cathode piece 6 face each other. Therefore, the positive electrode piece 5 and the negative electrode piece 6 can be inserted into the holes in the fixed state so as to face each other in parallel by the electrode piece holder 7 as shown in FIGS. 5 and 6.

The electrode piece holder 7 includes members 7a and 7b having two semicircular shapes, and the members 7a and 7b have parallel grooves 8a in which the anode piece 5 and the cathode piece 6 are inserted and held. , 8b) are formed on the surfaces facing each other. In the state where the positive electrode piece 5 and the negative electrode piece 6 are accommodated in the parallel grooves 8a and 8b, as shown in FIG. 5, the bolt 9 is arranged from the top of the one member 7a to the other member ( By being fastened to the bolt fastening hole 10 formed in 7b), the electrode piece holder 7 can hold the positive electrode piece 5 and the negative electrode piece 6 in parallel with each other, as shown in FIG. It becomes possible.

Therefore, when the electrode piece holder 7 is used, the wire-type plasma electrode rod according to the present invention is inserted into a hole formed in the rock in a state facing in parallel with each other, and thus has an advantage of shortening the rocking work time.

As described above, according to the wire type plasma rock electrode according to the present invention, since it has a relatively simple structure as compared with the conventional plasma rock electrode, the manufacturing cost is low, and the rock force generated during plasma rock is the electrode. Since the degree to which it is transmitted to is weak, the elasticity of the electrode rod due to the reaction force may be weak, and thus has the advantage that the same effect can be obtained with a simple structure compared with the conventional.

Claims (2)

A cathode cable connected to a brass rod connected to a cathode of a power supply at one end; A cathode piece having a plate shape connected to the other end of the cathode cable and supplied with a cathode current from a power supply through a cathode cable; An anode cable connected to one end of a brass rod connected to an anode of a power supply unit; An electrode rod having a plate shape connected to the other end of the positive electrode cable, the positive electrode piece being supplied with a positive current from the power supply through the positive electrode cable. The electrode rod of claim 1, wherein the electrode pieces are fixed to face the electrode piece holder in parallel.