KR101017585B1 - Power supply for dual-mode plasma torch - Google Patents

Abstract

The mixed plasma torch is a device that includes an appropriate amount of non-traveling arc in the transition arc to solve the instability of the operation, which is a problem of the transition plasma torch.

Conventional hybrid plasma torch power supplies use two rectifiers, but the present invention utilizes a single rectifier and two insulated gate bipolar transistor stacks for non-complied arc and transition arc of mixed plasma torch. The amount of current can be adjusted. One of the two insulated gate bipolar transistor stacks determines the sum of the amounts of current in the non-flying and transitioning arcs, the opening time of which is constantly changing as the electrical conductivity changes in the arc path. On the other hand, the other determines the amount of current in the non-following arc, and its opening time is kept constant.

Compared to the case of using two rectifiers, the power supply device of the mixed plasma torch as described above can achieve the effect of saving the apparatus cost, stable installation, and prolonging the heating efficiency of the melt and the electrode life of the torch.

Mixed Plasma Torch, Insulated Gate Bipolar Transistor, Rectifier

Description

Power supply unit for hybrid plasma torch {POWER SUPPLY FOR DUAL-MODE PLASMA TORCH}

TECHNICAL FIELD The present invention relates to a power supply for a plasma torch, and more particularly, to a power supply for a mixed plasma torch that operates in a non-run and transition mode.

Recently, melting and vitrification methods using a plasma torch are increasingly used to stabilize hazardous waste such as incineration ash, asbestos or radioactive waste. Industrial arc plasma torches used to melt these metals or inorganics are divided into non-run and torch types by movable type, each having advantages and disadvantages.

Non-running torches operate stably without being affected by the object, but reduce energy transfer efficiency. The transitional torch has a high energy transfer efficiency of the object, but can only operate when the object is conductive and unstable because the arc is affected by the environment of the external gas. Thus, in general, a non-implementation torch is used as a means for heating nonmetals, and a transition torch is used as a means for heating metals. However, even non-metals have a certain degree of conductivity when they reach a molten state. Since it is much more economical to use transitional torches at this time, attempts have long been made to allow transitional torches to be applied to nonmetals as well. However, this approach has difficulty in igniting the arc and ensuring the stability of the arc.

To solve this difficulty, Retech of the United States has developed a dual mode plasma arc torch system. This system uses two rectifiers, first of which the torch operates in non-run mode and automatically switches to transition mode when the slag becomes conductive. The amount of current for both modes is then determined by the conductivity of the slag.

However, this method has a disadvantage in that the arc current of each operation mode is difficult to control independently and two separate rectifiers must be used. In addition, in order to maintain the stability of the arc, there is a disadvantage that one rectifier must always be operated so that a certain amount of non-following current is continuously supplied.

SUMMARY OF THE INVENTION An object of the present invention is to provide a power supply for a mixed plasma torch using one rectifier and two insulated gate bipolar transistor stacks to reduce installation costs, ensure the stability of the transition arc, improve the heating efficiency of the melt and the electrode life of the torch. There is.

The present invention provides a power supply of a mixed plasma torch comprising a non-flying arc and a transition arc, comprising: a rectifier for supplying current to the mixed plasma torch; And a pair of insulated gate bipolar transistor stacks (IGBT stacks) disposed in parallel with the rectifier and receiving current from the rectifier to control the amount of current to supply the mixed plasma torch. Disclosed is a power supply of a mixed plasma torch, characterized in that the mixed plasma torch operates in a non-run mode or a transition mode as the insulated gate bipolar transistor stacks control the amount of current in the non-traveling and transitioning arcs.

In addition, the insulated gate bipolar transistor stack may include: a first insulated gate bipolar transistor stack configured to determine a sum of an amount of current supplied to the non-running arc and the transition arc; And a second insulated gate bipolar transistor stack that determines a ratio of the amount of current supplied to the non-running arc and the transition arc, wherein the second insulated gate bipolar transistor stack is in a ratio of an on state or an off state. According to an embodiment of the present invention, there is disclosed a power supply apparatus for a mixed plasma torch, wherein the mixed plasma torch is operated in a non-run mode, a transition mode, or a mixed mode thereof.

In addition, each of the insulated gate bipolar transistor stacks includes a pair of insulated gate bipolar transistor choppers (IGBT choppers) turned on / off to control a current supplied to the mixed plasma torch. Disclosed is a power supply apparatus for a plasma torch.

The power supply of the hybrid plasma torch according to the present invention includes one rectifier and two insulated gate bipolar transistor stacks, thereby reducing the size of the power supply and thus reducing the cost. In addition, since the amount of current according to the mode can be adjusted, a low non-current current value is maintained to reduce the erosion speed of the torch nozzle.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is a view showing a power supply device 100 of the mixed plasma torch according to a preferred embodiment of the present invention, Figure 2 is a power supply device 100 of the hybrid plasma torch shown in Figure 1 is a mixed plasma torch 200 Schematic diagram showing the connected state. 1 and 2, the power supply device 100 of the mixed plasma torch according to the preferred embodiment of the present invention includes a rectifier 101, insulated gate bipolar transistor stacks 102 and 103, and a transformer 104. And a reactor 105, which operates in a constant current manner to stably adjust the amount of current of the non-flying arc 203 and the transition arc 204 of the mixed plasma torch 200.

The rectifier 101 supplies a current to the mixed plasma torch 200. In addition, the cathode (-) common terminal (grounding) of the rectifier 101 is connected to the enclosure of the melting furnace equipped with a mixed plasma torch 200.

The insulated gate bipolar transistor stacks 102, 103 are connected in parallel between the negative (-) output terminal and the positive (+) output terminal of the rectifier 101 and the first and second insulated gate bipolar transistor stacks 102, 103. ).

The output of the first insulated gate bipolar transistor stack 102 is connected to the rear electrode 201 of the mixed plasma torch, and the output of the second insulated gate bipolar transistor stack 103 is connected to the front electrode 202 of the mixed plasma torch. In addition, the cathode (-) common terminal of the first and second insulated gate bipolar transistor stacks 102 and 103 is connected to an enclosure of a melting furnace equipped with a mixed plasma torch 200. The first and second The two insulated gate bipolar transistor stacks 102, 103 each comprise two choppers 121, 131, such that the mixed plasma torch 200 operates in a non-run mode, a transition mode, or a mixed mode thereof. do.

The total current It (non-travel current Int + transition current Itr) supplied to the mixed plasma torch 200 is determined by the first insulated gate bipolar transistor 121, and the non-current current Int and transition The ratio of the current Itr is determined by the second insulated gate bipolar transistor 131. Here, the non-flying current Int is a current supplied to the non-flying arc 203 of the mixed plasma torch 200, and the transition current Itr is supplied to the transition arc 204 of the mixed plasma torch 200. Current. For example, when the mixed plasma torch 200 is to be operated in the non-run mode, the second insulating gate bipolar transistor 131 is turned on so that current flows through the front electrode 202. do. On the other hand, when the mixed plasma torch 200 is to be operated in the transition mode, the second insulated gate bipolar transistor 131 is turned off to prevent current from flowing to the front electrode 202.

In the initial stage of operation of the plasma melting furnace, the electrical resistance value Rmp of the molten metal is very high because of the slag layer 205. As a result, the second insulated gate bipolar transistor is impossible because the mixed plasma torch 200 cannot operate in the transition mode. At 131, most of the current flowing in the mixed plasma torch 200 is a non-transition current Int and a transition current Itr is only a few amperes or less.

As the non-run mode operation of the mixed plasma torch 200 proceeds, the slag layer 205 becomes electrically conductive, thereby reducing the electrical resistance value Rmp of the molten metal. As a result, the plasma torch 200 may operate in the mixed mode according to the ratio of the total resistance Rnt of the non-running current path and the total resistance Rtr of the transition current path. At this time, when the second insulation gate bipolar transistor 131 is turned off to increase the total resistance value Rnt of the non-implementation current path, the transition current amount Itr naturally occurs by the power supply device 100 of the mixed plasma torch of the constant current method. Will increase. In view of this in terms of the operating voltage of the mixed plasma torch 200, the transition voltage Vtr increases because the voltage V2 between the front electrode 202 and the metal layer 206 increases. At this time, when the electrical conductivity of the molten metal is too small to reach the operating limit voltage Vlink, the transition voltage Vtr does not increase any more.

The operation of the mixed plasma torch 200 is performed by adjusting the on / off time of the second insulated gate bipolar transistor 131 while the slag layer 6 in the melting furnace reaches a sufficient electric conductivity. This is achieved by controlling the current Itr at an arbitrary ratio. On the other hand, since the power supply device 100 of the mixed plasma torch operates in a constant current manner, when the total resistance Rtr of the transition current path increases, the first insulated gate bipolar transistor 121 is automatically turned on to perform the transition. The voltage Vtr increases and thus the non-following current Int also increases. This increase in non-travel current Int decreases the resistance of the plasma column and consequently decreases the overall resistance. Therefore, even if the electrical conductivity of the slug layer 6 in the melting furnace is low, the fluctuation range of the transition voltage Vtr is not large.

Transformer 104 changes the voltage having a value appropriate for the operation of rectifier 101.

The reactor 105 is installed between the insulated gate bipolar transistor stacks 102 and 103 and the plasma torch electrodes 201 and 202 and suppresses the inrush current of the torch.

As described above, the power supply apparatus of the hybrid plasma torch according to the present invention can control the amount of currents of the non-running arc and the transition arc by using one rectifier and two insulated gate bipolar transistors 121 and 131, compared to a general power supply apparatus. One rectifier is economical with one reduction. In addition, when two rectifiers are used, the non-current current must be continuously provided for the stability of the arc, but the present invention increases the efficiency of the electric arc energy because the reduction of the transition current automatically causes the increase of the non-performance residual. Done. In addition, in normal operation, the non-flying current can be kept below 10% of the transition current, so that the erosion rate of the torch electrode is reduced.

3 is a graph showing the behavior of transition and non-compliance voltage and current according to an increase in the resistance value of the arc in the power supply unit of the hybrid plasma torch shown in FIG. As shown in FIG. 3, when the resistance Rtr of the transition current path temporarily increases due to the input of waste in a furnace equipped with the mixed plasma torch 200, the voltage changes. have.

Specifically, at 13:05, the chopper 131 of the second insulated gate bipolar transistor stack 103 is appropriately turned on to maintain the non-running current Int (b) at about 30 amps, and after about 2 minutes. Let's take a look at the case of waste. Due to the effects of organic matter, dust, etc. contained in the waste immediately after the introduction, it can be seen that the transition current Itr (c) decreases while the voltage Vtr (d) of the transition plasma column increases by about 150 volts. Since the power supply is operated in a constant current manner, the non-current current Int (b) increases as the transition current Itr (c) decreases, and the non-run plasma column resistance Vnt decreases due to the increase of the current. The transition voltage Vnt (a) is rather reduced.

While the present invention has been described in connection with certain exemplary embodiments, it will be understood by those skilled in the art that various changes may be made without departing from the scope of the present invention.

1 is a view showing a power supply of the mixed plasma torch according to a preferred embodiment of the present invention.

FIG. 2 is a schematic view showing a power supply unit of the mixed plasma torch shown in FIG. 1 connected to the mixed plasma torch.

3 is a graph showing the behavior of transition and non-compliance voltage and current according to an increase in the resistance value of the arc in the power supply unit of the hybrid plasma torch shown in FIG.

Claims (3)

A power supply for a mixed plasma torch comprising a non-flying arc and a transition arc, One rectifier for supplying current to the mixed plasma torch; And A pair of insulated gate bipolar transistor stacks (IGBT stacks) disposed in parallel with the rectifier and receiving current from the rectifier to control the amount of current to supply the mixed plasma torch, The insulated gate bipolar transistor stacks, A first insulated gate bipolar transistor that determines a sum of an amount of current supplied to the non-running arc and the transition arc; And A second insulated gate bipolar transistor that determines a ratio of the amount of current supplied to the non-running arc and the transition arc, The second insulated gate bipolar transistor is configured to operate the mixed plasma torch in a non-run mode, a transition mode, or a mixed mode thereof, depending on a ratio of an on state or an off state. Torch power supply. delete The method of claim 1, Each of the insulated gate bipolar transistor stacks includes a pair of insulated gate bipolar transistor choppers (IGBT choppers) turned on and off to control the current supplied to the mixed plasma torch. Power unit.

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