KR100459315B1 - Plasma Torch with Hollow Electrodes for Hazardous Waste Treatment - Google Patents

Abstract

The present invention relates to a plasma torch for generating thermal plasma capable of incineration and melt solidification of hazardous wastes. The present invention relates to improved design of electrodes, gas injection rings, cooling lines, and the use and discharge characteristics of magnetic fields. The present invention relates to the fabrication of direct current non-feed type plasma torch with cavity type electrode which can extend electrode and torch life, improve torch thermal efficiency and diversify waste to be treated. Copper was used as the cathode 3 so that air could be used as an arc gas for complete incineration through pyrolysis of organic waste, and the shape of the electrode was hollow. In order to prevent the operation of the torch, the cathode point 61 and the anode point 62 are formed on the cylindrical wall surface of the electrode, and the length and diameter ratios of the cathode 3 and the anode 13 which allow the torch to have the maximum thermal efficiency are measured. The damage of the electrode and the torch body was minimized through the improvement of the coolant flow path, and the shape of the new electrodes (3, 13) and the gas injection method were devised to obtain a high discharge voltage at the same operating power and gas flow rate to lower the current. By extending the life of the electrode erosion reduction. In addition, the solenoid 15 is installed on the outer circumferential surface of the cathode 3 to increase the rotation of the cathode point 62 to prevent electrode erosion, and at the same time, increase the vortex movement of the arc gas in the cathode region by increasing the cathode diameter slightly larger than the anode diameter. The torch can be operated for a long time. These devices are equipped with high temperature and high heat capacity heat sources that are the core of incinerators and smelters, and can be used for pyrolysis and vitrification of various hazardous wastes such as municipal waste, industrial waste, hospital waste and radioactive waste.

Description

Plasma Torch with Hollow Electrodes for Hazardous Waste Treatment

The present invention relates to the design and fabrication of a plasma torch that generates thermal plasma capable of complete incineration by pyrolysis and vitrification by melting and solidification of various hazardous wastes discharged in the form of organic or inorganic substances. It has a cavity-type electrode to improve the design of electrode, gas injection ring, cooling line, component use, and discharge characteristics, to extend the life of electrode and torch, improve torch thermal efficiency, and diversify waste to be treated. DC non-feed type plasma torch development.

Plasma torch is a pollution-free source because it is easy to control the operation conditions and uses electricity and gas. It is very small in size and can provide high temperature and calorie, so it has been used for spraying, synthesis, refining and smelting of metal for a long time. come. In recent years, the disposal of waste by landfill has reached its limit due to the increase of hazardous waste, but the incineration of wastes by incineration is increasing. By generating secondary pollutants, it is causing new environmental pollution. In order to overcome such a situation, while treating a large amount of hazardous waste in a short time, the waste treatment method by thermal plasma which is a pollution-free source that does not pollute the surrounding environment is attracting attention. Hazardous waste treatment by thermal plasma has excellent characteristics that are distinguished from conventional incineration methods, but it has the disadvantage of high operating cost because electricity is used as a raw material. For this reason, although various types of plasma torches have existed for a long time, the technology of applying thermal plasma to the treatment of hazardous waste has been difficult to commercialize.

In addition, in order to thermally decompose an organic waste and burn it with a harmless and chemically stable element, it is necessary to use an air containing oxygen or a gas such as water vapor as an arc gas. However, the conventional rod-nozzle type plasma torch, which is most widely used for material processing such as plasma spraying, uses a cathode made of tungsten. When air or oxygen is used as an arc gas, tungsten, which is a cathode material, is oxidized. Erosion of the cathode greatly increases the electrode life is short, and there is a problem that the maintenance of the arc is difficult because hot electron emission is suppressed.

In addition, in order to treat hazardous wastes in which organic and inorganic materials are mixed, sufficient amount of heat must be delivered to the hazardous wastes for pyrolysis and vitrification, and sufficient amount of oxygen can be supplied to the arc gas to cause combustion reaction to the pyrolyzed elements. Should be The plasma torch must have a high output power in order to handle a large amount of hazardous waste. There are two ways to obtain a high output voltage by increasing the operating current and voltage. However, when the operating current increases, the electrode erosion increases, so that the electrode needs to be frequently replaced, so it is also required to obtain a high output by increasing the operating voltage.

Accordingly, there is a need for a plasma torch for hazardous waste treatment that can use a variety of arc gases, enable not only high power operation at low currents, but also to reduce the erosion rate of the electrode to extend the life of the electrode.

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems as described above, and an object of the present invention is to provide a plasma torch having a high voltage and thermal efficiency at the same input power operating conditions and prolonging the lifetime of a cathode.

Another object of the present invention is to provide a plasma torch using various arc gases including oxygen and the like.

In order to achieve the above object, the present invention improves the design of the electrode and the gas injection method. This makes it possible to use air as an arc gas, which enables low operating costs and diversification of the object to be treated, and enables complete pyrolysis treatment of the object, and enables high power operation even at low current, thereby reducing the erosion rate of the electrode. By reducing the operating life of the torch can be increased. In the range where the arc point exists inside the electrode, the ratio of diameter and length of the negative electrode and the positive electrode having the maximum thermal efficiency can be determined to enable more economical hazardous waste treatment. In addition, the cathode diameter is slightly larger than the anode diameter to increase the vortex movement inside the cathode, while a solenoid that applies an external magnetic field to the cathode surface is installed to increase the rotational speed of the arc point so that the cathode erosion rate is almost the same as the anode erosion rate. The level can be reduced to extend the life of the electrode.

Other objects and advantages of the present invention will become apparent from the following detailed description.

1 is a cross-sectional view of a cavity plasma torch of the present invention.

2 is a cross-sectional view of a cavity cathode and anode of a cavity plasma torch in accordance with the present invention.

3 is a detailed cross-sectional view near the gas injection portion of the cavity-type plasma torch according to the present invention.

Figure 4 is a cross-sectional view showing the flow of coolant and arc gas inside the cavity-type plasma torch according to the present invention.

5 is a principle diagram in which an arc point is determined inside a cavity electrode of a cavity plasma torch according to the present invention;

Figure 6 is a side view of the gas injection ring of the cavity-type plasma torch according to the present invention.

7 is a principle diagram illustrating the function of the solenoid of the cavity-type plasma torch according to the present invention.

<Explanation of symbols for the main parts of the drawings>

1: cathode body 2: cathode body support 3: cathode

4 Insulation part I 5 Insulation part II 6 Insert I

7 gas injection ring 8 anode body 9 insert II

10: outer body I 11: bipolar body support 12: outer body II

13: anode 14: front lid 15: solenoid

16: Solenoid Body I 17: Solenoid Body II

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

1 is a cross-sectional view showing a torch according to the present invention, in which the torch has two hollow cylindrical electrodes made of copper and has a cathode 3 and an anode 13, and has an arc for vortexing to stabilize the arc. It has a basic structure of the gas injection ring (7) for injecting gas. In addition, it insulates the negative electrode body (1), the negative electrode body support (2), the negative electrode (3) and the positive electrode (13), which supplies negative power (-) and cooling water to the torch at the same time, and serves as a path for the arc gas. Insulating parts 4 and 5 and the positive electrode body forming the passages of the positive electrode body 8 and the positive electrode body support 11 and the cooling water, which fix the portion I (4) and the insulating part II (5) and the positive electrode 13 ( 8) Inserts I (6) and Inserts II (9) supporting the torch, the outer body II (12) and the front lid (14), which cover the interior of the torch and finish the exterior, and serve as a positive power path. Outer body I (10) which supplies +) and serves as outlet of cooling water, solenoid (15) installed to apply magnetic field in plasma from the outside, solenoid body I (16) and solenoid body II (17) to protect the solenoid ) And the like.

Here, the negative electrode body 1 is provided with a screw groove 18 inside the left end to facilitate the supply of negative power and cooling water at the same time, and six bolt holes 19 for connecting with the negative electrode body support 2 are provided. Pierced Six bolt holes 20 are drilled in the cathode body support 2 to be coupled to the cathode body 1, and the solenoid body I 16 is fixed to the cathode body support 2 by screws 23.

When the cathode 3 is made of copper, gas containing oxygen, that is, air and water vapor can be used as an arc gas, and since the electrodes 3 and 13 are hollow cavity types, the cathode point is not fixed at one position. This can reduce the erosion of the cathode 3. The negative electrode 3 is connected to the negative electrode body 1 by a screw thread 22 disposed at the bottom thereof.

Figure 2 is a cross-sectional view well showing the structure of the cavity and cathode of the plasma torch according to the present invention. The upper end of the cavity type cathode 3 is wider (26) near the gas injection ring (7) as shown in FIG. 2 and then gradually narrowed (25) to the inner wall of the cathode (3). The lower end of the positive electrode 13 was manufactured in a shape 27 widening in the positive electrode body 8 and then narrowing 28 and then widening toward the inner wall of the positive electrode 13. In order to facilitate the initial discharge of the arc, the distance between the cathode 3 and the closest portions 25 and 28 of the anode 13 is maintained at 2 mm. On the other hand, if the distance between 26 and 29 is closer than 25 and 28, the initial discharge occurs between 26 and 29, causing damage to 29, which is a part of the anode body, and even damaging even the gas injection ring (7). For the protection of (8) and the gas injection ring (7), the distance between 26 and 29 was made larger than the distance between 25 and 28. In addition, 24 and 27, 26 and 29 were symmetrical with each other so that the arc gas was smoothly incident into the electrodes 3 and 13. That is, as a whole, the portion where the cathode 3 and the anode 13, through which the gas flows through the gas injection ring 7, flows, is close to each other, is formed in the shape of the cathode 3 and the anode 13 facing each other.

3 is a cross-sectional view near the gas injection portion of the cavity-type plasma torch according to the present invention. Insulation portions I (4) and II (5) serve to electrically insulate the cathode 3 and the anode 13. As shown in FIG. 1, the insulation portion I (4) is disposed on the cathode body support 2 and the solenoid body I 16 downward, the insulation portion II (5), the insert I (6) and the outer body I (10) upward. ) Insulation portion I 4 and outer body I 10 are connected to each other by six bolt holes 31 and 40, and injecting arc gas into electrodes 3 and 13 into insulation portion I 4. The hole 30 is drilled. The insulating portion II (5) is fixed to the negative electrode body support (2) and the insulating portion I (4) by the combination of the screw thread 22 of the negative electrode (3) and the screw groove 22 of the negative electrode body (1) do. In addition, as shown in FIG. 3, the insulating portion II (5) has a hole 33 for injecting an arc gas into the space 36 including the gas injection ring 7, the insulating portion II 5, and the anode body 8. ) And a hole 34 that is a passage for the coolant. The holes 33 and 34 were drilled three and six, respectively, so that the arc gas and the cooling water flowed uniformly. The insert I (6) is connected to the insulator II (5) by the combination of the screw groove 32 in the insulator II (5) and the thread 32 in the insert I (6). It serves to fix I (4) and insulation part II (5). Insert II (9) is coupled to the insert I (6) and screwed (35) to fix the positive electrode body (8) to the insulating portion (II) 5 and the gas ring (7). Insert I (6) and Insert II (9), together with the insulation part II (5), the anode body (8), and the outer body (I) as shown in Fig. 4, create a cooling water passage (50, 55). give.

The gas injection ring 7 includes an arc gas existing in the empty space 36 formed of the insulating portion II 5, the anode body 8, and the gas ring 7 shown in FIG. 3. Injects to the inside. In addition, 18 small holes 37, which were obliquely drilled at uniform intervals, were processed in the gas injection ring 7 so that the arc gas more uniformly enters the electrodes 3,13. When the front lid 14 is coupled to the outer body II (12) and the screw type 45, the positive electrode 13 is fixed to the positive electrode body (8). The anode body 8 has six holes 38 that serve as passages for cooling water, and is coupled to the anode body support 11 made of an insulating part and screwed 39 to reduce the weight of the torch. The outer body I 10 serves to supply a positive power (+) to the torch together with the role of the outlet 41 of the cooling water, and is coupled to the waste treatment furnace by the screw groove 43. The outer body II 12 has eight holes 44 drilled at the bottom thereof, and is connected to the eight holes 42 of the outer body I 10 by bolts, and the front lid 14 and the screw upwards. Connected to equation (45). Outer body II (12) and the front lid (14) is a part that is exposed to high temperature because it is located in the incinerator during hazardous waste treatment. Therefore, they were cooled with water to withstand the high temperatures inside the incinerator, and their diameters were made smaller than those at the bottom, which not only looked beautiful but also reduced the weight of the torch.

4 is a cross-sectional view illustrating a path through which coolant flows to prevent the torch from being damaged by heat received from an arc plasma generated in an electrode and a high temperature in an incinerator. The coolant injected into the negative electrode body 1 passes through four obliquely perforated holes 21 through the inner wall 48 of the negative electrode body, and annular form 49 between the negative electrode body support 2 and the negative electrode 3. Through the pipes, it goes to the six obliquely drilled holes 34 installed in the insulation portion II (5). Then, through the annular tube 50 consisting of the insulation part II (5), the insert I (6) and the anode body (8), it passed through six holes (38) which are obliquely drilled in the anode body (8). Later, the anode body 8, the anode body support 11, and the annular tube 51 between the anode 13 and the anode body support 11, the front lid 14 and the outer body II (12) Pass through the ring-shaped tube (52, 53) consisting of. Finally, the outside of the torch with a hole 41 formed in the outer shell body I (10) flowing through the annular body (54, 55) consisting of the anode body (8), insert II (9) and outer shell I (10) To be discharged. At this time, the hole 21 and the hole 34 are drilled in the same direction, and the hole 38 is obliquely oriented in the opposite direction to cause the vortex movement of the coolant so that the coolant is formed in the annular tube 49 in the holes 21, 34 and 38. 50, 51) to continue to rotate in the same direction to flow the cooling water more evenly. In addition, the cross-sectional area of the holes 21, 34, 38 through which the coolant flows is 1.5 to 2 times larger than the cross-sectional area of the annular pipes 49, 50, 51, so that the coolant has a ring-shaped pipe (49, 50, 51). Cooling of the electrodes 3, 13 was facilitated by keeping the flow rate fast when flowing. On the contrary, the parts 52, 53, 54, and 55 cooling the front lid 14, the outer body II 12 and the outer body I 10 have a relatively large cross-sectional area, thereby reducing the pressure resistance and allowing the coolant to smoothly flow inside the torch. To flow.

The arc gas is supplied from the hole 30 drilled in the insulating portion I (4) and passes through the annular space 56 consisting of the insulating portion I (4) and the insulating portion II (5) and to the insulating portion II (5). After passing through the three openings 33, they enter the space 36 consisting of the insulating portion II (5), the gas injection ring (7) and the anode body (8). Then, it enters between the negative electrode 3 and the positive electrode 13 through 18 holes 37 uniformly drilled in the gas injection ring 7.

Referring to Figure 5 will be described the principle that the arc point is formed inside the cavity electrode. The arc gas incident from the gas injection ring 7 flows inside the electrodes 3 and 13 in the manner shown in FIG. Looking at the flow of the arc gas inside the cathode (3) as shown in the side wall (57) of the cathode (3) by the vortex movement of the arc gas injected from the gas injection ring (7) the arc gas continues to push toward the bottom wall (58) However, the speed decreases as it approaches the bottom wall 58. The arc gas, once hit by the bottom wall 58, is directed toward the outlet 59 of the torch, so that the arc gas has a velocity in the axial direction z near the center of the cathode 3. In the region of the anode 13, there is only a speed at which the arc gas is directed toward the torch outlet 59, and in the axial direction of the arc gas by friction with the side wall 60 of the anode 13 while being directed toward the torch outlet 59. Speed decreases. Therefore, the dynamic force of the arc gas acts in the -z direction on the side wall 57 of the cathode 3 and in the z direction on the side wall 60 of the anode 13. Once the arc is discharged, as can be seen in b of FIG. 5, a current density and a magnetic field induced from the arc are generated. At this time, the Lorentz force j × Bθ represented by the vector product of the current density j and the magnetic field strength Bθ induced from the arc appears in the z direction near the cathode point 62 and in the -z direction near the anode point 61. . However, as shown in FIG. 5A, since the dynamic force of the gas acts in the -z direction near the cathode point 62 and in the z direction near the anode point 61, Lorentz near the arc points 61 and 62. The force and the dynamic force of the body are opposite to each other, and the positions of the arc points 61 and 62 are determined where the Lorentz force and the dynamic force of the body are equal. Thus, the position of the arc points 61 and 62 is determined by the axial speed of the arc gas that generates the dynamic current of the gas and the operating current that is the source of the Lorentz force.

In order to operate the torch for a long time, the erosion of the electrodes 3 and 13 should be reduced. Since the erosion of the electrodes 3, 13 is proportional to the magnitude of the current density concentrated at the arc points 61, 62, the operating current should be reduced to reduce the erosion of the electrodes 3,13. However, incineration of a large amount of hazardous waste requires the use of a high power torch, so that erosion of the electrodes 3 and 13 is reduced while operating the torch at high power while increasing the operating voltage. In order to increase the operating voltage, the length of the arc 63 must be increased, and for this purpose, the dynamic force of the gas must be increased. At the same arc gas flow rate, the dynamic force of the gas is proportional to the intensity of the vortex motion as the arc gas enters the electrodes 3, 13. As shown in FIG. 6, the holes 37 drilled in the gas injection ring 7 were obliquely formed to increase the vortex movement of the arc gas, and 18 holes were drilled at equal intervals to make the arc gas velocity uniform in the rotational direction. . In addition, in order to maintain the vortex movement of the arc gas generated in the gas injection ring 7 to the inside of the electrode, as shown in FIG. 2, the injection parts 24 and 27 of the electrode were smoothly processed, and the injection parts 24 and 27 of the electrode. ) And the center position of the hole 37 drilled in the gas injection ring (7) to match. If the outer diameter of the gas injection ring 7 is not larger than the diameters of the electrodes 3 and 13, the effect of the vortex motion is reduced because the arc gas lacks a space for causing the vortex motion. Therefore, in order to generate sufficient vortex motion of the arc gas, the following relation between the negative electrode 3 diameter d _c and the gas injection ring 7 outer diameter D is given.

(D≥2.5d _c )

A commonly used method to increase the operating voltage is to increase the arc length by increasing the flow rate of the arc gas. At this time, if the length of the arc toward the cathode 3 is too long, an arc point is generated on the bottom wall 58 of the cathode 3 and the arc point is fixed at one position, thereby rapidly increasing the erosion of the cathode 3. In addition, if the length of the arc toward the anode 13 is longer, an arc point exists outside the torch outlet 59, which damages the torch body. On the contrary, if the arc length is too short compared to the length of the electrodes 3 and 13, the heat loss from the high temperature of the thermal plasma to the electrode wall surfaces 57 and 60 increases, thereby reducing the thermal efficiency of the torch. In the present invention, in the range where the arc points 61 and 62 exist on the side walls 57 and 60 of the electrodes 3 and 13, the cathode length l _c and the anode length l _a having the highest thermal efficiency of the torch are tested through experiments. The decision was made as follows.

(12d _c ≤l _c ≤20d _c , 12d _a ≤l _a ≤15l _c .)

The phenomenon in which the negative electrode 3 has a higher erosion rate than the positive electrode 13 was found in the torch performance test, and the present invention devised two methods to make the erosion rates of the positive electrodes 3 and 13 the same. Since the bottom wall 58 of the cathode 3 is blocked, the vortex motion of the arc gas generated in the gas injection ring 7 is much stronger in the anode 13 region than in the cathode 3 region. Arc gas is therefore out more easily escape toward the large diameter cathode electrode 3, the negative electrode 3, the diameter d _c was slightly larger than the cathode 13, _a diameter d to increase the swirling motion in the area. In order to reduce the erosion of the electrodes 3 and 13, the arc points 61 and 62 should be kept moving without being fixed at one position on the surface of the electrodes 3 and 13. Although the arc points 61 and 62 rotate even by the vortex motion of the arc gas, the most obvious way to extend the life of the electrodes 3 and 13 is to apply a magnetic field from the outside in the z direction.

7 is a principle diagram illustrating the solenoid function of the cavity type plasma torch according to the present invention. When the magnetic field 64 in the z direction is applied to the cathode point 62 from the outside, the Lorentz force j × Bθ that appears from the current density 65 of the r component and the intensity of the external magnetic field in the z direction at the cathode point 62 is obtained. It appears in the θ direction, and as a result, the cathode point 62 is forcibly rotated, so that the erosion of the electrode at the cathode point 62 is greatly reduced. For this reason, the present invention is provided with a solenoid 15 to hang the magnetic field in the z direction from the outside, and has a solenoid body I (16) and a solenoid body II (2) for protecting the solenoid (15).

While the invention has been described with reference to specific embodiments, it will be apparent to those skilled in the art that various changes and modifications can be made therein within the spirit of the invention and the appended claims. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense of the invention.

According to the present invention, by improving the design of the electrode and the gas injection method to obtain a high voltage under the same input power operating conditions and the use of various arc gases, it is possible to use air as an arc gas, thereby reducing the operating cost and diversification In addition, it enables complete pyrolysis treatment and enables high power operation even at low current, thereby increasing the lifetime of the torch by reducing the erosion rate of the electrode. The coolant flow path is designed to have a structure and a flow rate that can cool not only the electrode but also the torch body exposed to high temperature, thereby minimizing damage to the electrode and torch. The ratio of the diameter and the length of the anode and the anode having the maximum thermal efficiency in the range where the arc point exists inside the electrode was made to enable more economical hazardous waste treatment. In addition, the cathode diameter is slightly larger than the anode diameter to increase the vortex movement inside the cathode, while a solenoid that applies an external magnetic field to the cathode surface is installed to increase the rotational speed of the arc point so that the cathode erosion rate is almost the same as the anode erosion rate. The level can be reduced to extend the life of the electrode.

Claims (10)

In a plasma torch generating thermal plasma capable of processing hazardous waste, the hollow cylindrical cathode 3, the hollow cylindrical anode 13 provided in front of the cylindrical cathode, between the cylindrical cathode and the cylindrical anode And a gas injection ring (7) for supplying an arc gas to the gas injection ring (7), wherein the diameter of the gas injection ring (7) is at least 2.5 times the diameter of the cylindrical cathode (3), and the cylindrical cathode and the anode are adjacent to each other. Both ends of the cylindrical cathode and the anode are formed in a convex shape facing each other, the plasma torch. 2. The plasma torch of claim 1, further comprising a solenoid coil (15) around the cylindrical cathode. The plasma torch of claim 1, wherein the closest distance between the cylindrical cathode and the cylindrical anode is 2 mm. 3. The plasma torch of claim 1 or 2, wherein a diameter of the cylindrical cathode is larger than a diameter of the cylindrical anode. According to claim 1 or 2, wherein the length l of _a length l _c and the cylindrical anode of the cylindrical cathode, and satisfies the relationship of the following _{12d c ≤l c ≤20d c, 12d} a ≤l a ≤15l c, Wherein d _c is the diameter of the cathode and d _a is the diameter of the anode. 3. The plasma torch as claimed in claim 1 or 2, wherein the gas injection ring (7) comprises a plurality of holes which are inclined at regular intervals at equal intervals along the circumferential direction. 3. The plasma torch of claim 1 or 2, wherein the cylindrical cathode is made of copper. 3. The plasma torch as claimed in claim 1 or 2, further comprising a coolant passage formed by a single line for cooling the body of the torch and the cylindrical electrode (3,13). The cooling water passage includes an annular tube (49, 50, 51) and holes 21, 34, 38 through which the coolant flows, wherein the cross-sectional area of the hole through which the coolant flows is annular cross-sectional area. Plasma torch, characterized in that 1.5 to 2 times larger. 3. The plasma torch of claim 1 or 2, wherein the torch body, the cylindrical cathode, and the cylindrical anode are assembled by bolts or screws.