KR20100096384A - Dual type plasma arc torch - Google Patents

Abstract

PURPOSE: A dual type plasma an arc torch is provided to generate arc by installing a nonconductive material between a cylinder type positive electrode and an outside negative electrode. CONSTITUTION: A nozzle-type negative electrode(30) keeps a gap from the other end of a cylinder type positive electrode(20). An external negative electrode is located at the front of the nozzle-type negative electrode. Gas service pipes(40,50) supply plasma gas between the cylinder type positive electrode and the nozzle-type negative electrode. A controller measures the voltage between the cylinder type positive electrode and the external negative electrode.

Description

Dual type Plasma Arc Torch

The present invention has a simple internal structure for easy maintenance and inspection, prevents damage to the torch surface and electrodes, extends its lifespan, and prevents the arcing of the torch from being interrupted by interruption of energization by non-conductive materials. A plasma arc torch.

In general, the plasma arc torch includes the negative electrode 902 and the positive electrodes 903 and 904 as shown in FIG. 1, and heats the gas with an electric arc generated between the negative electrode 902 and the positive electrodes 903 and 904. It is used to treat objects such as wastes by forming

The negative electrode 902 is installed at the inner end of the cylindrical body 900 and the positive electrodes 903 and 904 are installed at the inner surface of the cylindrical body 900. The positive electrode includes an intermediate positive electrode 903 and a nozzle positive electrode 904, and an insulating portion 905 is provided between the negative electrode and the positive electrode.

The nozzle positive electrode 904 is installed at the opposite end of the inner surface of the cylindrical body 900, and the intermediate positive electrode 903, also known as a start-up electrode, forms a path for injecting gas to protect the electrode and facilitates initial discharge. In order to be installed between the negative electrode 902 and the nozzle positive electrode 904.

Between the intermediate positive electrode 903 and the negative electrode 902, a nitrogen gas injection hole 906 for injecting nitrogen gas to protect the negative electrode and a plasma gas injection hole 907 for generating high-temperature plasma are provided. A cooling tube 908 for cooling the negative electrode 902, the middle positive electrode 903, and the nozzle positive electrode 904 is provided.

Plasma arc torch having such a component is used to be mounted to the reactor 920, a waste injection hole 909 for injecting waste between the reactor 920 and the nozzle positive electrode 904 is installed and torch operation Plasma jet 911 is launched into the furnace. In this case, the electrode 930 may be installed at a position other than the inside of the torch such as a furnace floor.

Looking at the internal structure of the torch, in the conventional torch, the solenoid coil bundle 910 is installed on the positive electrode 904 to move the generation point of the arc to extend the life of the electrode.

The torch case 901 uses general stainless steel, which installs the torch 900 in the reactor 920 and generates arcs in the case during operation, causing partial wear or melting of the furnace by torch operation. Attaching to the case may cause surface damage to the torch.

However, the above-described conventional plasma arc torch has the following problems.

1) As the case of torch uses stainless steel which is generally used, it is attached to the reactor and when the torch is operated, abrasion on the surface of the shell may occur due to short with the shell of the reactor, or skin damage may occur due to scattering of the melt in the furnace. there is a problem.

2) The utility lines connected to the torch are composed of eight utility lines such as four coolant lines, two electric lines, and two air lines, so that the surroundings of the torch are complicated and there is a safety risk.

3) In addition, since the electrode of the torch is composed of positive electrode, middle positive electrode and negative electrode, it is difficult to disassemble and combine for maintenance and inspection of the torch because of complicated structure.

4) There is a problem that the torch operation may be interrupted when the torch is operated in a unstable operation depending on the furnace condition.

The present invention for solving such a conventional problem, the internal structure is simple, maintenance and inspection is easy, and the torch operation is not only possible by extending the life by preventing damage to the surface of the torch and electrodes, but also to It is an object of the present invention to provide a dual plasma arc torch capable of continuous operation even in an unstable situation.

The present invention for achieving the above object, the cylindrical positive electrode; A nozzle type negative electrode arranged to maintain a gap between the other end of the cylindrical positive electrode; An external negative electrode positioned in front of the nozzle type negative electrode; And a gas supply pipe for introducing plasma gas between the cylindrical positive electrode and the nozzle type negative electrode, wherein the nozzle type negative electrode is connected with a negative electrode wire and a negative electrode auxiliary wire with a resistance, and a current is supplied to the nozzle type negative electrode. When the voltage rises above the reference voltage by measuring the voltage between the external negative electrode and the cylindrical positive electrode while a current is supplied to the cylindrical positive electrode and the external negative electrode without supplying the negative electrode auxiliary together with the external negative electrode It provides a dual plasma arc torch, characterized in that the control unit is provided to control the current supply to the wire.

The other end is coupled to one end of the cylindrical positive electrode, and a coolant inlet tube is provided to which the coolant flows. The cylindrical positive electrode has a passage for guiding the coolant introduced into the coolant inlet tube at one end in the direction of an outer circumferential surface thereof. And an injection hole is formed at one side of the inner space, and the other end is opened, and the gas supply pipe is coupled to one end of the cylindrical positive electrode while receiving the cooling water inlet pipe, and the plasma positive electrode A first gas supply pipe for supplying to the injection hole of the second gas supply pipe, and a second gas supply pipe for supplying plasma gas to a gap formed between the cylindrical positive electrode and the nozzle type negative electrode, the first gas supply pipe being disposed to accommodate the first gas supply pipe, The second gas supply pipe is disposed in a state of accommodating the other end, and the other end is connected to the nozzle type negative electrode. It is preferably made is provided with a cooling water discharge pipe which is fed via the cooling water inlet pipe discharging the coolant passed through the outer peripheral surface of the cylindrical positive electrode.

In addition, the injection hole of the cylindrical positive electrode is preferably inclined so that the plasma gas injected through the injection hole is rotated.

In addition, it is preferable to provide a ferrite ring on the outer circumferential surface of the cooling water inlet pipe so as to easily ignite by filtering the high frequency noise component generated during the torch ignition.

In addition, in order to prevent the outer circumferential surface of the cooling water discharge pipe from being damaged by a melt that is melted and scattered when installed in a reactor, it is preferable to form an alumina coating layer on the outer circumferential surface of the cooling water discharge pipe.

In addition, in order to extend the life of the electrode of the torch, it is preferable to include an operation unit for moving the generation point of the arc by arbitrarily or automatically adjusting the plasma gas supply amount of the first gas supply pipe and the second gas supply pipe.

The dual plasma arc torch of the present invention maintains arc generation even in an unstable situation in which it is difficult to maintain arc generation due to non-conductive material located between the cylindrical positive electrode and the external negative electrode during the transfer operation. It is easy to repair and check because the internal structure is simple, and to prevent the damage of the torch surface and the electrode has the effect of extending the life.

Hereinafter, the dual plasma arc torch of the present invention will be described with reference to Examples. The scope of the present invention is not limited to the following Examples.

2 is a block diagram schematically showing the configuration of a dual plasma arc torch, which is an embodiment of the present invention, and FIG. 3 is a cross-sectional view showing a cross-sectional state of the plasma arc torch, which is an embodiment of the present invention.

Plasma arc torch of the present invention as shown in Figure 1 and 2, the cooling water inlet tube 10, the cylindrical positive electrode 20; A nozzle type negative electrode 30 disposed to maintain the other end and the gap of the cylindrical positive electrode 20; An external negative electrode 310 located in front of the nozzle type negative electrode 30; It comprises a gas supply pipe (40, 50), a cooling water discharge pipe 60 and the controller 810 for introducing a plasma gas between the cylindrical positive electrode 20 and the nozzle type negative electrode 30.

The cooling water inlet pipe 10 is for supplying cooling water for cooling the cylindrical positive electrode 20, the nozzle type negative electrode 30, and the like, and is made of a conductive material and has one end electrically connected to the positive electrode. In FIG. 3, one end of the cooling water inlet pipe 10 is provided with a positive electrode connecting part 110 made of a tubular conductive material.

The ferrite ring 710 may be placed on the outer circumferential surface of the coolant inlet pipe 10 so as to filter the high frequency noise generated when the torch is ignited by using a magnetic attenuation effect peculiar to ferrite.

The cylindrical positive electrode 20 has a cylindrical shape with one end closed and the other end opened, and one end is coupled to the other end of the cooling water inlet pipe 10.

One end of the cylindrical positive electrode 20 is formed with a passage 210 for guiding the cooling water supplied to the cooling water inlet pipe 10 to the outer circumferential surface of the cylindrical positive electrode 20, and having a spray hole in the inner space. 220 is formed. An inlet of the passage 210 is formed on one end of the cylindrical positive electrode 20, and an outlet is formed on the outer circumferential surface of one end of the cylindrical positive electrode 20. The cylindrical positive electrode 20 is cooled by the coolant flowing into the passage 210.

Meanwhile, in FIG. 3, the cylindrical positive electrode 20 includes a cylindrical positive electrode portion 20a and a holder portion 20b coupled to one end of the cylindrical positive electrode portion 20a, but is not limited thereto. It may be formed as.

The nozzle type negative electrode 30 is disposed on the other side of the cylindrical positive electrode 20 so that a constant gap G is maintained from the other end of the cylindrical positive electrode 20.

 The nozzle type negative electrode 30 is for non-feeding operation at the beginning of operation, and is coupled to one end of the cooling water discharge pipe 60.

The first gas supply pipe 40 is for supplying plasma gas to the injection holes 220 formed in the cylindrical positive electrode 20, and is disposed in a state in which the cooling water inflow pipe 10 is accommodated. The plasma gas supplied through the first gas supply pipe 40 is injected into the cylindrical positive electrode 20 through the injection hole 220 of the cylindrical positive electrode 20. It is preferable to incline the injection hole 220 so that the plasma gas injected through the injection hole 220 of the cylindrical positive electrode 20 is turned to smoothly generate the plasma flame.

In addition, the second gas supply pipe 50 is for supplying plasma gas to the gap G between the cylindrical positive electrode 20 and the nozzle type negative electrode 30. The first gas supply pipe 40 is connected to the second gas supply pipe 40. It is placed in a housed state. An auxiliary pipe 550 of a non-conductive material having a gas passage is provided between the second gas supply pipe 50 and the gap G. The plasma gas supplied through the second gas supply pipe 50 is supplied between the gaps G through the gas passage 552 of the auxiliary pipe 550. As shown in FIG. 3, the injection ring 560 in which the injection hole 562 is inclined is preferably provided in order to rotate and supply the plasma gas to the gap G.

On the other hand, one side of the auxiliary pipe 550 is provided with a stepped groove 554, one side of the groove 554 is a passage through which the coolant heat exchanged in contact with the outer peripheral surface of the cylindrical positive electrode 20 ( 556 is provided.

In addition, the negative electrode fixing part 350 is fixed to the nozzle type negative electrode 30 and supplies cooling water introduced into the groove 554 of the auxiliary tube 550 to the outer circumferential surface of the nozzle type negative electrode 30. .

In addition, the control unit 810 may move the generation point of the arc by arbitrarily or automatically adjusting the plasma gas supply amount of the first gas supply pipe 40 and the second gas supply pipe 50. The generation point may be moved by the controller 810 arbitrarily or automatically, thereby extending the life of the torch electrode.

In addition, the plasma arc torch of the present invention is configured to be separated from the positive electrode and the negative electrode, there is an advantage that the operator can easily replace the positive electrode or negative electrode when excessive wear occurs due to long time operation.

The cooling water discharge pipe 60 is supplied to the cooling water inlet pipe 10 to discharge the cooling water heat exchanged through the cylindrical positive electrode 20 and the nozzle type negative electrode 30 to the outside. The supply pipe 50, the auxiliary pipe 550, and the negative electrode fixing part are disposed in a state of being accommodated. The cooling water discharge pipe 60 is made of a conductive material and is electrically connected to the negative electrode, and the other end is coupled to the nozzle type negative electrode 30, and the positive electrode connection part 610 having a cooling water discharge port 612 formed at an outer circumferential surface of one end thereof. It is provided.

On the other hand, the outer peripheral surface of the cooling water discharge pipe 60 is provided with an alumina (Al ₂ O ₃ ) coating layer to prevent surface damage caused by the arc generated during the torch operation after mounting the reactor, and also prevent damage due to the adhesion of scattered slag Not only can it be done, but it can also prevent damage caused by contact with the shell.

In addition, the external negative electrode is for a transfer type operation and is provided in front of the nozzle type negative electrode 30. When the nozzle type negative electrode 30 is capable of supplying electricity to the bottom or the outside of the reactor after the non-feeding operation, the transfer operation is performed by supplying current to the external negative electrode.

Meanwhile, as shown in FIG. 2, a negative electrode wire 821 and a negative electrode auxiliary wire 823 having a resistor 830 are connected to the nozzle type negative electrode 30. The cathode wire 821 is for non-feeding operation by supplying a current to the nozzle type negative electrode 30 during initial operation, and the cathode auxiliary wire is supplied with current to the external negative electrode 310 for transfer operation. In the case of performing a non-conductive material or the like between the cylindrical positive electrode 20 and the external negative electrode 310 to prevent the interruption of the torch when the situation occurs when the arc generation of the torch is to prevent the interruption. .

That is, when the controller measures the voltage between the cylindrical positive electrode 20 and the external negative electrode 310 to rise above the reference voltage value, the controller supplies current to the negative electrode auxiliary wire as well as the external negative electrode 310. Maintain the arc. When a non-conductive material or the like is located between the external negative electrode 310 and the cylindrical positive electrode 20 to interfere with electricity supply, the voltage between the external negative electrode 310 and the cylindrical positive electrode 20 increases rapidly. The control unit 810 detects this and supplies a current to the cathode auxiliary wire, so that if the arc maintenance is unstable during the transfer type operation and normal operation is impossible, the control unit 810 automatically switches to the non transfer type operation condition, and then meets the transfer type operation condition. Can automatically return to the transfer mode and maintain the arc. At this time, the reference voltage value is a voltage value of an unstable arc holding state during the transfer operation, and is determined by the control unit configuration and the experiment.

On the other hand, the resistance of the negative electrode auxiliary wire is preferably configured to be water cooled by a separate cooling water.

4 is a view schematically showing the flow of coolant inside the plasma arc torch. As shown in FIG. 4, the cooling water introduced through the cooling water inlet tube 10 is discharged through the cooling water discharge tube 60 via the outer circumferential surface of the cylindrical positive electrode and the nozzle type negative electrode 30. In the case of the conventional plasma arc torch, the torch is cooled by having a total of four coolant inlet tubes and a coolant outlet tube, one pair at each of the positive electrode and the negative electrode. By efficiently cooling the torch, the structure is greatly simplified, making it easy to manufacture, repair and inspect.

In addition, the cooling water inlet tube 10 and the cooling water discharge tube 60, which is also used as the electric wire, are cooled by a water cooling method by using the cooling water inflow tube 10 and the cooling water discharge tube 60 as a function of the electric wire. As a result, the current can be supplied to the torch using a small diameter wire compared to the air-cooled type, and thus there is an advantage of facilitating operations such as wire connection and removal.

1 is a schematic cross-sectional view of a conventional plasma arc torch.

Figure 2 is a block diagram schematically showing the configuration of a dual plasma arc torch which is an embodiment of the present invention,

3 is a cross-sectional view showing a cross-sectional state of the plasma arc torch,

4 is a diagram schematically illustrating a coolant flow inside a plasma arc torch.

*** Explanation of symbols for main parts of drawing ***

10: cooling water inlet pipe,

20: cylindrical positive electrode,

30: nozzle type negative electrode,

40: first gas supply pipe,

50: second gas supply pipe,

60: cooling water discharge pipe

Claims (6)

A cylindrical positive electrode; A nozzle type negative electrode arranged to maintain a gap between the other end of the cylindrical positive electrode; An external negative electrode positioned in front of the nozzle type negative electrode; It comprises a gas supply pipe for introducing a plasma gas between the cylindrical positive electrode and the nozzle type negative electrode, The nozzle type negative electrode is connected to the negative electrode wire and the negative electrode auxiliary wire with resistance, respectively, When the voltage rises above the reference voltage by measuring the voltage between the external negative electrode and the cylindrical positive electrode while the current is supplied to the cylindrical positive electrode and the external negative electrode without supplying current to the nozzle type negative electrode. Dual plasma arc torch, characterized in that the control unit for controlling the supply of current to the negative auxiliary wire together with an external negative electrode. According to claim 1, The other end is coupled to one end of the cylindrical positive electrode is provided with a cooling water inlet tube, the cooling water flows in, The cylindrical positive electrode is formed at one end with a passage for guiding the cooling water introduced into the cooling water inlet pipe in the direction of the outer circumferential surface, the injection hole is formed on one side of the internal space, the other end is open; The gas supply pipe may include a first gas supply pipe which is coupled to one end of the cylindrical positive electrode while supplying the cooling water inlet pipe, and supplies a plasma gas to the injection hole of the cylindrical positive electrode, and the first gas supply pipe. A second gas supply pipe disposed in an accommodating state and supplying plasma gas to a gap formed between the cylindrical positive electrode and the nozzle type negative electrode, The second gas supply pipe is disposed in a state of receiving the other end is coupled to the nozzle-type negative electrode and is supplied through the cooling water inlet pipe is provided with a cooling water discharge pipe for discharging the cooling water via the outer peripheral surface of the cylindrical positive electrode Dual plasma arc torch. The dual type plasma arc torch of claim 2, wherein the injection holes of the cylindrical positive electrode are inclined to pivot the plasma gas injected through the injection holes. The dual type plasma arc torch of claim 2, wherein a ferrite ring is provided on an outer circumferential surface of the coolant inlet pipe. The dual type plasma arc torch of claim 2, wherein an alumina coating layer is formed on an outer circumferential surface of the cooling water discharge pipe. The dual type plasma arc torch of claim 2, wherein the controller moves the generation point of the arc by respectively adjusting the plasma gas supply amounts of the first gas supply pipe and the second gas supply pipe.

Images