KR101227717B1 - Steam plasma torch - Google Patents

Abstract

The present invention relates to a steam plasma torch, the use of steam as the plasma gas required to generate a flame fired from the positive electrode portion is generated by the secondary pollution source containing nitrogen oxides (NOx), which is a cause of air pollution in the flame Can be prevented more easily, and since the decomposition components of steam can directly participate in the formation and reaction of the atmosphere in the furnace, it is possible to establish optimum process conditions, and in particular, damage such as excessive wear caused by long flame generation can be avoided. When it occurs in the positive electrode portion, the operator has an effect that it is possible to more easily replace and repair only the damaged portions of the entire positive electrode portion or the first positive electrode portion and the second positive electrode portion damaged.

Description

Steam Plasma Torch {STEAM PLASMA TORCH}

The present invention can more easily prevent the generation of secondary pollution sources including nitrogen oxides (NOx), which is a cause of air pollution, by using steam as the plasma gas required to generate the flames emitted from the positive electrode portion. Of course, since the decomposition components of steam can directly participate in the formation and reaction of the atmosphere in the furnace, it is possible to establish the optimum process conditions, and furthermore, especially when damage such as excessive wear due to long flame generation occurs in the positive electrode portion. The present invention relates to a steam plasma torch in which an operator can easily replace and repair only the damaged part of the positive electrode part or the first positive electrode part and the second positive electrode part damaged.

In general, plasma has been studied in the United States and the Soviet Union for the purpose of nuclear fusion by using deuterium which is infinitely large in the sea. Hanaro's plasma process, which has more than 80% conversion efficiency from electric energy to thermal energy, is in the spotlight.

The plasma is dissociated and ionized by the local high heat of the electric arc generated by the high frequency between the adjacent negative electrode and the positive electrode to be in the plasma state.

Recently, many examples of using air as a plasma gas for use in melting ore or waste treatment by generating only high heat without accompanying chemical reactions such as oxidation and reduction (deoxidation) have been proposed.

Plasma generated heat may reach several hundred thousand degrees, but it is used in fields other than nuclear fusion purposes in the range of thousands to tens of thousands of degrees. Especially, the plasma used in the metal industry has a temperature range of 5,000 ° C to 10,000 ° C.

As such, since plasma has high temperature and high enthalpy properties, the plasma is commonly used for hazardous waste melting, plasma spraying, diamond film formation, and metal processing.

As a representative apparatus having the characteristic of generating such a high temperature plasma gas, there is a plasma arc torch.

The plasma arc torch has a negative electrode and a positive electrode to form a plasma by arc heat between these negative and positive electrodes.

Specifically, the conventional plasma arc torch is typically provided with a negative electrode and a positive electrode inside the cylindrical case.

The negative electrode is installed at one end inside the case, the positive electrode has a cylindrical shape and is installed at the other end inside the case.

The positive electrode also serves as a nozzle. In this case, the positive electrode extends to the outside of the case, that is, to the plasma discharge end.

In addition, an intermediate electrode for initial discharge may be provided between the negative electrode and the positive electrode, and the negative electrode and the intermediate electrode are insulated with an insulator.

In the plasma process, it is necessary to accurately control the process atmosphere since the change of all phases participating in the reaction must be accurately predicted.

The gases used in plasma technology are mostly inert gases.

Therefore, these gases make the process atmosphere chemically neutral.

However, sometimes the atmosphere can be partially or wholly controlled to cause oxidation, reduction, nitriding and chloride reactions.

Argon, hydrogen, oxygen, nitrogen and air are used as the plasma gas, and each gas has characteristics.

Argon is used to stabilize the arc discharge and is also used as a heat transfer medium to heat the treatment.

It is also used as a heat transfer medium in a processing vessel even after decomposition.

Hydrogen is used for the purpose of reduction or deoxidation.

Nitrogen is relatively inexpensive and has the effect of increasing strength and corrosion resistance for some target materials.

Oxygen can react with all elements except He, Ne, Ar, etc., and thus can produce compounds in all temperature ranges.

Air has the advantage of being very rich in quantity and inexpensive, and can be used where treatment and chemical reactions are not important, without special requirements for the medium.

Therefore, air is a plasma gas that is widely applied for melting or waste treatment.

However, since nitrogen is present in the air component of about 21%, nitrogen oxides (NOx) may be generated in the order of tens of thousands of ppm at the high temperature generated by the arc.

In comparison, when steam is used as a plasma gas, the steam is water (H ₂ O), so when it is decomposed into hydrogen and oxygen, it is not a secondary source of pollution. There are advantages to it.

The present inventors can more easily prevent the generation of secondary pollutants, including nitrogen oxides (NOx), which are a cause of air pollution, by using steam as the plasma gas necessary to generate the flames emitted from the positive electrode portion. Of course, since the decomposition components of steam can directly participate in the formation and reaction of the atmosphere in the furnace, it is possible to establish the optimum process conditions, and furthermore, especially when damage such as excessive wear due to long flame generation occurs in the positive electrode portion. The present invention proposes a steam plasma torch which can easily replace and repair only the damaged part of the positive electrode part or the damaged part of the first positive electrode part and the second positive electrode part.

The present invention can more easily prevent the generation of secondary pollution sources including nitrogen oxides (NOx), which is a cause of air pollution, by using steam as the plasma gas required to generate the flames emitted from the positive electrode portion. Of course, since the decomposition components of steam can directly participate in the formation and reaction of the atmosphere in the furnace, it is possible to establish the optimum process conditions, and furthermore, especially when damage such as excessive wear due to long flame generation occurs in the positive electrode portion. It is an object of the present invention to provide a steam plasma torch that can easily replace and repair only the damaged part of the entire positive electrode part or the first positive electrode part and the second positive electrode part damaged by the worker.

The present invention for achieving the above object is a negative electrode unit; A positive electrode portion including a first positive electrode portion provided in an upper direction of the negative electrode portion so as to maintain a gap with an upper side of the negative electrode portion, and a second positive electrode portion provided on an upper side of the first positive electrode portion to communicate with the first positive electrode portion; It provides a steam plasma torch comprising a; and a steam and air supply pipe for supplying steam and air between the negative electrode portion and the positive electrode portion.

Here, the negative electrode portion and the first negative electrode portion is coupled to the lower side of the positive electrode portion detachably by a fastening member; A second negative electrode part having an upper side detachably fastened by the fastening member to a lower side of the first negative electrode part; A third negative electrode part having an upper side detachably fastened by the fastening member to a lower side of the second negative electrode part; And a fourth negative electrode part accommodated in the first, second and third negative electrode parts, the lower side being detachably fastened to the lower side of the third negative electrode part by the fastening member.

In addition, a coolant inlet tube having a coolant introduced therein is provided at one side of the first negative electrode unit, and a coolant outlet for discharging the coolant introduced into the coolant inlet tube is formed inside the fourth negative electrode unit, and inside the first negative electrode unit. It is preferable that a coolant guide path for guiding the coolant introduced into the coolant inlet pipe to the coolant outlet.

Further, it is preferable that an intermediate electrode is provided in the middle of the upper side of the first negative electrode part, and a negative electrode is provided in the upper side of the fourth negative electrode part in a state of being located in the lower direction of the intermediate electrode so as to maintain a gap with the lower side of the intermediate electrode. .

The high melting point alloy including tungsten is preferably provided at the center of the negative electrode.

In addition, an argon gas inflow pipe through which argon gas flows is provided at one side of the second negative electrode part, and the argon gas introduced into the argon gas inflow pipe inside the first negative electrode part is disposed on the lower side of the intermediate electrode and the negative electrode. It is preferable that an argon gas guide path leading to the gap formed between the upper sides is formed.

In addition, a pipe body is provided to accommodate the positive electrode portion therein, a coolant inlet pipe is provided on one side of the pipe body to introduce the coolant into the inside of the pipe body, and discharges the coolant introduced into the coolant inlet pipe to the other side of the pipe body. Cooling water discharge pipe is provided, it is preferable that a cooling water guide path for guiding the cooling water introduced into the cooling water inlet pipe to the cooling water discharge pipe inside the pipe body.

In addition, it is preferable that grooves are formed at a predetermined interval on the outer circumferential surface of the positive electrode portion.

The present invention can more easily prevent the generation of secondary pollution sources including nitrogen oxides (NOx), which is a cause of air pollution, by using steam as the plasma gas required to generate the flames emitted from the positive electrode portion. Of course, since the decomposition components of steam can directly participate in the formation and reaction of the atmosphere in the furnace, it is possible to establish the optimum process conditions, and furthermore, especially when damage such as excessive wear due to long flame generation occurs in the positive electrode portion. There is an effect that the operator can more easily replace and repair only the damaged portions of the entire positive electrode portion or the first positive electrode portion and the second positive electrode portion of the positive electrode portion.

1 is a cross-sectional view schematically showing a steam plasma torch which is an embodiment of the present invention.
2 is an enlarged partial cross-sectional view of the negative electrode portion,
3 is a partially enlarged cross-sectional view taken along the line A-A of FIG.
4 is a partially enlarged cross-sectional view schematically illustrating the flow of the coolant introduced into the coolant inlet tube provided at one side of the first negative electrode unit;
FIG. 5 is a partially enlarged cross-sectional view schematically illustrating a flow of argon gas introduced into an argon gas inlet pipe provided on one side of a second negative electrode part;
6 is an enlarged partial cross-sectional view of the positive electrode unit;
FIG. 7 is a partially enlarged cross-sectional view schematically illustrating a flow of coolant introduced into a coolant inlet pipe provided on one side of a pipe.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.

1 is a cross-sectional view schematically showing a steam plasma torch which is an embodiment of the present invention.

As shown in FIG. 1, a steam plasma torch, which is an embodiment of the present invention, includes a negative electrode part 10, a positive electrode part 20, and a steam and air supply pipe 30.

FIG. 2 is a partially enlarged cross-sectional view illustrating the enlarged negative electrode part 10, FIG. 3 is a partially enlarged cross-sectional view taken along the line A-A of FIG. 2, and FIG. 4 is a coolant inlet provided at one side of the first negative electrode part 100. Partial enlarged cross-sectional view schematically showing the flow of the coolant flowed into the pipe (180).

First, in order to facilitate maintenance of the negative electrode unit 10 and replacement and repair of only the negative electrode unit 10 or the corresponding damaged part when damage such as wear occurs in the negative electrode unit 10,

As shown in FIG. 2, the negative electrode unit 10 includes a first negative electrode unit 100, a second negative electrode unit 110, a third negative electrode unit 120, and a fourth negative electrode unit 130. Can be.

The first negative electrode unit 100 may be detachably fastened by an upper fastening member 40 to the lower side of the positive electrode unit 20.

The upper side of the second negative electrode unit 110 may be detachably fastened by the fastening member 40 in a state accommodated inside the lower side of the first negative electrode unit 100.

The upper side of the third negative electrode unit 120 may be detachably fastened by the fastening member 40 in a state accommodated inside the lower side of the second negative electrode unit 110.

The fourth negative electrode unit 130 may be vertically accommodated in the first, second and third negative electrode units 100, 110, and 120.

The lower side of the fourth negative electrode unit 130 may be detachably fastened to the lower side of the third negative electrode unit 120 by the fastening member 40.

The upper outer circumferential surface of the first negative electrode unit 100, the upper outer circumferential surface of the second negative electrode unit 110, the upper outer circumferential surface of the third negative electrode unit 120, and the lower outer circumferential surface of the fourth negative electrode unit 130 are each '. A stepped groove 170 of a '' shape may be formed.

The stepped groove 170 may include a first stepped groove 171, a second stepped groove 172, a third stepped groove 173, and a fourth stepped groove 174.

The first stepped groove 171 may be formed to have a predetermined depth recessed inwardly of the first negative electrode part 100 on the upper outer circumferential surface of the first negative electrode part 100.

The second stepped groove 172 may be recessed in a predetermined depth into the second negative electrode part 110 on the upper outer circumferential surface of the second negative electrode part 110.

The third stepped groove 173 may be formed to have a predetermined depth recessed into the third negative electrode part 120 on the upper outer circumferential surface of the third negative electrode part 120.

The fourth stepped groove 174 may be formed to have a predetermined depth recessed into the fourth negative electrode part 130 on the lower outer circumferential surface of the fourth negative electrode part 130.

The fastening member 40 may be composed of an annular horizontal plate 40a and an annular vertical wall 40b.

The annular vertical wall 40b may be integrally formed at the edge of the top surface of the annular horizontal plate 40a.

The fastening member 40 including the annular horizontal plate 40a and the annular vertical wall 40b has a first fastening member 410, a second fastening member 420, and a third fastening member 430, respectively. ) And the fourth fastening member 440.

The horizontal plate 40a of the first fastening member 410 may be accommodated in the first step groove 171.

An inner circumferential surface of the vertical wall 40b of the first fastening member 410 may be screwed to a lower outer circumferential surface of the tubular body 90 to be described later to accommodate the positive electrode portion 20 therein.

The horizontal plate 40a of the second fastening member 420 may be accommodated in the second stepped groove 172.

An inner circumferential surface of the vertical wall 40b of the second fastening member 420 may be screwed to a lower outer circumferential surface of the first negative electrode part 100.

The horizontal plate 40a of the third fastening member 430 may be accommodated in the third step groove 173.

An inner circumferential surface of the vertical wall 40b of the third fastening member 430 may be screwed to a lower outer circumferential surface of the second negative electrode unit 110.

The horizontal plate 40a of the fourth fastening member 440 may be accommodated in the fourth step groove 174.

An inner circumferential surface of the vertical wall 40b of the fourth fastening member 440 may be screwed to a lower outer circumferential surface of the third negative electrode part 120.

Next, in order to cool the negative electrode unit 10 while the flame is fired from the positive electrode unit 20,

As shown in FIG. 2, a coolant inlet tube 180 through which coolant is introduced is provided at one side of the first negative electrode unit 100, and the coolant inlet tube 180 is disposed inside the fourth negative electrode unit 130. Cooling water outlet 50 for discharging the introduced cooling water may be formed.

The cooling water inlet pipe 180 may be connected to a known cooling water supply unit (not shown) through a supply line 41 including a tubular hose or a tubular pipe.

The fourth negative electrode unit 130 may include a lower negative electrode unit 131 and an upper negative electrode unit 132.

The lower negative electrode unit 131 may be vertically accommodated in the second and third negative electrode units 110 and 120.

The lower end of the upper negative electrode unit 132 may be vertically accommodated in the first negative electrode unit 100 in a state accommodated inside the upper side of the lower negative electrode unit 131.

The cooling water outlet 50 may include a lower cooling water outlet 510 and an upper cooling water outlet 520.

The lower cooling water outlet 510 may be formed in the lower negative electrode unit 131.

The upper coolant outlet 520 may be formed in the upper negative electrode unit 132 to communicate with the lower coolant outlet 510.

A cooling water guide path 60 may be formed inside the first negative electrode part 100 to guide the cooling water introduced into the cooling water inlet pipe 180 to the cooling water discharge port 50.

As shown in FIG. 4, an auxiliary pipe 61 for forming the coolant guide path 60 may be provided inside the first negative electrode part 100.

The auxiliary pipe 61 may be composed of a first auxiliary pipe 611, a second auxiliary pipe 612 and a third auxiliary pipe 613.

The upper negative electrode part 132 may be accommodated in the first auxiliary tube 611.

An upper side of the lower negative electrode unit 131 may be accommodated in an inner lower side of the first auxiliary tube 611.

A through hole 611a may be formed at one side of the middle portion and the other side of the middle portion of the first auxiliary tube 611.

The first auxiliary body 611 may be accommodated in the second auxiliary body 612.

One side and the other side of the second auxiliary pipe 612 may be formed with a through hole 612a in communication with the through hole 611a of the first auxiliary pipe 611.

The through hole 612a may be inclined downward toward the through hole 611a of the first auxiliary pipe body 611 from the upper end to the lower end.

The second auxiliary pipe 612 may be accommodated in the third auxiliary pipe 613.

The coolant guide path 60 may include a first coolant guide path 610, a second coolant guide path 620, and a third coolant guide path 630.

The first coolant guide path 610 may be formed between the upper negative electrode part 132 and the first auxiliary pipe 611 to communicate with the coolant outlet 50.

The second coolant guide path 620 may be formed between the second auxiliary pipe 612 and the third auxiliary pipe 613.

The third coolant guide path 630 may be formed between the third auxiliary pipe 613 and the first negative electrode part 100 to communicate with the second coolant guide path 620.

As the cooling water supply unit (not shown) introduced into the cooling water inlet pipe 180 through the supply line 41 is shown in FIG. 4, the third cooling water guide path 630 → the second cooling water guide path. 620 → a through hole 612a of the second auxiliary pipe 612 → a through hole 611a of the first auxiliary pipe 611 → the first coolant guide path 610 → the cooling water discharge port 50 Pass through each of them sequentially may be discharged to the heat exchange state to the outside of the negative electrode portion (10).

Next, as shown in FIG. 2, an intermediate electrode 140 and a negative electrode 150 may be provided.

The intermediate electrode 140 may be provided in the middle of the upper side of the first negative electrode unit 100.

A negative electrode is formed on the upper side of the upper negative electrode unit 132 of the fourth negative electrode unit 130 in a state in which the lower side of the intermediate electrode 140 and the gap G ₂ are maintained in a lower direction of the intermediate electrode 140. 150 may be provided.

The gap G ₁ and the middle formed between the lower side of the first positive electrode unit 210 and the upper side of the first negative electrode unit 100, which will be described later, on the inside of the intermediate electrode 140. A through hole 141 communicating with the gap G ₂ formed between the lower side of the electrode 140 and the upper side of the negative electrode 150 may be formed.

Next, an arc generated between the intermediate electrode 140 and the negative electrode 150 when power is supplied to the negative electrode unit 10 and the positive electrode unit 20 to fire a flame from the positive electrode unit 20. In particular, in order to prevent corrosion from occurring in the negative electrode 150 and the like to extend the life of the negative electrode 150, the whole of the negative electrode 150 is made of a high melting point alloy including tungsten or the like, or FIG. 2. As can be seen in the central portion of the negative electrode 150, a high melting point alloy 160 that conforms to tungsten or tungsten may be provided in a fixed state inserted into a predetermined depth.

5 is a partially enlarged cross-sectional view schematically illustrating a flow of argon gas introduced into an argon gas inflow pipe 70 provided at one side of the second negative electrode unit 110.

Next, an arc furnace generated between the intermediate electrode 140 and the negative electrode 150 when power is supplied to the negative electrode unit 10 and the positive electrode unit 20 to fire a flame from the positive electrode unit 20. In order to more securely protect the negative electrode 150 and the like so that the negative electrode 150 is not corroded,

As shown in FIG. 5, an argon gas inflow pipe 70 through which argon gas is introduced is provided at one side of the second negative electrode part 110, and the argon gas inflow pipe ( An argon gas guide path 80 may be formed to guide the argon gas introduced into the interior 70 to the gap G ₂ formed between the lower side of the intermediate electrode 140 and the upper side of the negative electrode 150.

The argon gas inlet pipe 70 may be connected to a known argon gas supply unit (not shown) through a supply line 71 including a tubular hose or a tubular pipe.

As shown in FIGS. 3 and 5, the argon gas guide path 80 may include a first argon gas guide path 810 and a second argon gas guide path 820.

As shown in FIG. 3, the first argon gas guide path 810 is located behind the through hole 612a while maintaining a predetermined distance from the through hole 612a of the second auxiliary pipe 612. The second auxiliary pipe 612 may be vertically formed in the inside of one side and the inside of the other side.

The second argon gas guide path 820 is an upper side of the first auxiliary pipe 611 and the second auxiliary pipe 612 so as to communicate with the first argon gas guide path 810 and the gap G ₂ , respectively. It can be vertically formed between the upper side of ().

The argon gas introduced into the argon gas inlet pipe 70 through the supply line 71 by the argon gas supply unit (not shown) is internal to the second negative electrode unit 110 as shown in FIG. 5. The first argon gas guide path 810 → the second argon gas guide path 820 may be sequentially supplied to the gap G ₂ .

6 is an enlarged partial cross-sectional view of the positive electrode unit 20.

Next, as shown in FIG. 6, the positive electrode unit 20 is composed of a first positive electrode unit 210 and a second positive electrode unit 220.

The first positive electrode part 210 and the second positive electrode part 220 may be made of various materials, but are preferably easily purchased on the market, are easy to process, and have excellent electrical conductivity. It is preferred to be made of a suitable pure copper material.

The first positive electrode part 210 has an upper portion of the first negative electrode part 100 of the negative electrode part 10 such that the gap G ₁ is maintained with an upper side of the first negative electrode part 100 of the negative electrode part 10. It is perpendicular to the direction.

The second positive electrode unit 220 may be vertically provided on the upper side of the first positive electrode unit 20 to communicate with the first positive electrode unit 210.

An upper side of the first positive electrode unit 210 may be accommodated in a screwed state inside the lower side of the second positive electrode unit 220.

Next, as shown in FIG. 6, a tubular body 90 made of stainless steel or the like for accommodating the positive electrode unit 20 therein may be provided.

In addition, in order to cool the positive electrode unit 20 while the flame is emitted from the positive electrode unit 20,

As shown in FIG. 6, a coolant inlet pipe 910 is provided at one lower side of the tubular body 90 to introduce coolant into the tubular body 90, and the coolant inlet tube is located at the bottom of the tubular body 90. Cooling water discharge pipe 920 for discharging the cooling water introduced into the 910 may be provided.

The cooling water inlet pipe 910 may be connected to a known cooling water supply unit (not shown) through a supply line 42 including a tubular hose or a tubular pipe.

Furthermore, a coolant guide path 930 may be formed in the pipe 90 to guide the coolant introduced into the coolant inlet 910 to the coolant discharge pipe 920.

As shown in FIG. 6, an auxiliary pipe 200 for forming the coolant guide path 930 may be provided inside the pipe 90.

The auxiliary pipe 200 may be composed of a first auxiliary pipe 201 and a second auxiliary pipe 202.

The first positive electrode unit 210 of the positive electrode unit 20 may be accommodated in the first auxiliary tube 201.

A through hole 201a may be formed at one lower side and the other lower side of the first auxiliary tube 201.

The through hole 201a may be inclined upward in the direction from the lower end to the upper end in the direction of the first positive electrode unit 210.

An upper side of the first auxiliary tube 201 may be accommodated in the lower side of the second auxiliary tube 202.

The coolant guide path 930 may include a first coolant guide path 931 and a second coolant guide path 932.

The first coolant guide path 931 is vertically formed between the first positive electrode unit 210 and the first auxiliary tube 201 and between the second positive electrode unit 220 and the second auxiliary tube 202. Can be.

The second coolant guide path 932 is in communication with the first coolant guide path 931 and the coolant discharge pipe 920 between the first auxiliary pipe body 201 and the lower side of the pipe body 90 and the second. It may be formed vertically between the auxiliary tube 202 and the upper side of the tube (90).

7 is a partially enlarged cross-sectional view schematically showing the flow of the coolant introduced into the coolant inlet pipe 910 provided on one side of the tube 90.

The cooling water introduced by the cooling water supply unit (not shown) into the cooling water inlet pipe 910 through the supply line 42 is the through hole 201a of the first auxiliary pipe 201 as shown in FIG. 7. The first coolant guide path 931 → the second coolant guide path 932 → sequentially pass through the coolant discharge pipe 920 may be discharged in a state of being heat-exchanged to the outside of the tube 90.

Next, the contact area between the coolant passing through the coolant guide path 930 and the positive electrode unit 20 is increased to improve the heat exchange efficiency of the coolant and the positive electrode unit 20, thereby improving the cooling efficiency of the positive electrode unit 20. To maximize,

As shown in FIG. 7, grooves 21 may be formed on the outer circumferential surface of the positive electrode unit 20 at regular intervals in the vertical direction.

The groove 21 may be recessed to a predetermined depth in the inward direction of the positive electrode unit 20 on the outer circumferential surface of the positive electrode unit 20.

Next, the steam and air supply pipe 30 is provided on the other side of the lower lower portion of the tubular body 90 so as to be located in the lower direction of the cooling water discharge pipe 920 as shown in FIGS.

The steam and air supply pipe 30 is formed between the upper side of the first negative electrode unit 100 of the negative electrode unit 10 and the lower side of the first positive electrode unit 210 of the positive electrode unit 20. ₁ ) to supply steam and air sequentially.

The steam and air supply pipe 30 may be connected to a known steam and air supply unit (not shown) through a supply line 43 including a tubular hose or a tubular pipe.

When the power is supplied to the negative electrode portion 10 and the positive electrode portion 20 is extended in the positive electrode portion 20 in the vertical direction by an arc generated between the intermediate electrode 140 and the negative electrode 150 The flame that occurs in the state passes through the inside of the positive electrode unit 20 and is fired outward from the positive electrode unit 20.

On the other hand, the positive electrode unit 20 may be mounted in a known melting chamber in which the waste to be melted is accommodated to fire a flame into the melting chamber to melt the waste.

At this time, although not shown in the drawing, the melting chamber has a temperature sensor including a known thermocouple for measuring the temperature of the high temperature heat generated in the melting chamber;

And a control unit (not shown) for controlling the steam and air supply unit (not shown) by comparing the temperature value measured by the temperature sensor with a preset reference temperature value.

When the temperature value measured by the temperature sensor is equal to or greater than a reference temperature value preset in the controller (not shown),

The control unit (not shown) is the steam and air supply unit (not shown) through the steam and air supply pipe 30 and the upper side of the first negative electrode unit 100 of the negative electrode unit 10 and the positive electrode unit 20 While controlling the amount of air supplied to the gap (G ₁ ) formed between the lower side of the first positive electrode unit 210 of the lower and completely stop,

The steam and air supply unit (not shown) is formed on the upper side of the first negative electrode unit 100 of the negative electrode unit 10 and the first positive electrode unit 210 of the positive electrode unit 20 through the steam and air supply pipe 30. Steam is supplied to the gap (G ₁ ) formed between the lower side of the).

When the temperature value measured by the temperature sensor is equal to or less than the reference temperature value preset in the controller (not shown),

The control unit (not shown) is the steam and air supply unit (not shown) through the steam and air supply pipe 30 and the upper side of the first negative electrode unit 100 of the negative electrode unit 10 and the positive electrode unit 20 While controlling the amount of steam supplied to the gap (G ₁ ) formed between the lower side of the first positive electrode unit 210 to be completely stopped while,

The steam and air supply unit (not shown) is formed on the upper side of the first negative electrode unit 100 of the negative electrode unit 10 and the first positive electrode unit 210 of the positive electrode unit 20 through the steam and air supply pipe 30. It is controlled to supply air to the gap (G ₁ ) formed between the lower side of the).

Steam staying in the positive electrode portion 20 due to the positive electrode portion 20 composed of a flame and the first and second positive electrode portions 210 and 220 extending in the vertical direction in the positive electrode portion 20. The residence time of can be relatively long, and in this process, the decomposition efficiency of steam which is decomposed into hydrogen and oxygen components rather than air pollution sources can be further improved.

On the other hand, the rate of damage including wear and the like on the second positive electrode unit 220 is relatively higher than that of the first positive electrode unit 210 during the process of firing the flame by the positive electrode unit 20.

In this case, the worker may separate and repair the second positive electrode unit 220 that is relatively damaged in the first positive electrode unit 210.

According to the present invention, as the plasma gas is required to generate the flame emitted from the positive electrode unit 20, a secondary pollution source including nitrogen oxide (NOx), which is a cause of air pollution, is generated in the flame. It can be easily prevented, and since the decomposition components of steam can directly participate in the formation and reaction of the atmosphere in the furnace, it is possible to establish the optimal process conditions, and in particular, damage such as excessive wear caused by long flame generation can be caused by the positive electrode. In the case of the part 20, the worker may easily replace only the damaged part of the positive electrode part 20 or the damaged part of the first positive electrode part 210 and the second positive electrode part 220 of the positive electrode part 20. There is an advantage to repair.

10; A negative electrode portion 20; Positive Electrode,
30; Steam and air supply lines.

Claims (8)

A negative electrode portion 10;
The first positive electrode unit 210 provided in an upper direction of the negative electrode unit 10 so that the gap G ₁ and the upper side of the negative electrode unit 10 is maintained, and the first positive electrode unit 210 communicates with the first positive electrode unit 210. A positive electrode unit 20 including a second positive electrode unit 220 provided above the first positive electrode unit 210;
It comprises a; and the steam and air supply pipe 30 for supplying steam and air between the negative electrode unit 10 and the positive electrode unit 20,
The negative electrode unit 10 includes a first negative electrode unit 100, the upper side of which is detachably fastened by the fastening member 40 to the lower side of the positive electrode unit 20;
A second negative electrode part 110 having an upper side detachably fastened to the lower side of the first negative electrode part 100 by the fastening member 40;
A third negative electrode part 120 having an upper side detachably fastened by the fastening member 40 to a lower side of the second negative electrode part 110;
The fourth negative electrode part accommodated in the first, second and third negative electrode parts 100, 110 and 120, and the lower side is detachably fastened to the lower side of the third negative electrode part 120 by the fastening member 40. (130); steam plasma torch characterized in that it comprises a.
The method of claim 1,
One side of the first negative electrode unit 100 is provided with a coolant inlet tube 180 through which the coolant flows.
A cooling water discharge port 50 for discharging the cooling water introduced into the cooling water inlet pipe 180 is formed in the fourth negative electrode unit 130.
The steam plasma torch, characterized in that the cooling water guide path 60 for guiding the cooling water introduced into the cooling water inlet pipe 180 to the cooling water discharge port 50 inside the first negative electrode unit 100. .
The method of claim 1,
The intermediate electrode 140 is provided in the middle of the upper side of the first negative electrode unit 100,
The negative electrode 150 is provided on the upper side of the fourth negative electrode unit 130 in a state in which the lower side of the intermediate electrode 140 and the gap (G ₂ ) is maintained in the lower direction of the intermediate electrode 140. Steam plasma torch.
The method of claim 3,
Steam plasma torch, characterized in that the high melting point alloy 160 including tungsten is provided in the center of the negative electrode 150.
The method of claim 3,
An argon gas inflow pipe 70 through which argon gas is introduced is provided at one side of the second negative electrode part 110,
The gap G ₂ formed between the lower side of the intermediate electrode 140 and the upper side of the negative electrode 150 with the argon gas introduced into the argon gas inflow pipe 70 inside the first negative electrode unit 100. Steam plasma torch, characterized in that the argon gas guide (80) is guided to.
The method of claim 1,
A tubular body 90 is provided to accommodate the positive electrode portion 20 therein,
Cooling water inlet pipe 910 is provided on one side of the tubular body 90 to introduce the coolant into the tubular body 90,
The other side of the tube 90 is provided with a cooling water discharge pipe 920 for discharging the cooling water introduced into the cooling water inlet pipe 910,
Steam plasma torch, characterized in that the coolant flow path 930 for guiding the coolant introduced into the coolant inlet pipe (910) to the coolant discharge pipe (920) is formed in the tube (90).
The method of claim 1,
Steam plasma torch, characterized in that the groove 21 is formed at a predetermined interval on the outer peripheral surface of the positive electrode unit 20. delete

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