KR20200117367A - Plasma torch with guide-type front electrode for non-transfer torch operation - Google Patents

Abstract

Disclosed is a plasma torch with a guide type front electrode for a non-transfer torch operation. The plasma torch includes: a hollow rear electrode having a closed end and an open end on one side and the other side, respectively; a hollow front electrode having an inlet and an outlet, wherein the inlet is disposed coaxially with the rear electrode so that the inlet faces the open end of the rear electrode at a predetermined interval; and a hollow outer body having a diameter and length sufficient to accommodate the rear electrode, the front electrode, and a gas supply port, and accommodating the rear electrode, the front electrode, and the gas supply port therein. The front electrode is insulated from an outer body by an insulating material, and the insulating material is glass wool. The plasma torch has improved durability by preventing side arcing which occurs during the operation of the plasma torch.

Description

Plasma torch with guide-type front electrode for non-transfer torch operation {Plasma torch with guide-type front electrode for non-transfer torch operation}

The present invention relates to a plasma torch equipped with a guide-type front electrode for operating a non-transfer-type torch, and more particularly, to a plasma torch with a guide-type front electrode for preventing side arcing during a non-transfer-type torch operation. will be.

In order to melt the material in a high temperature state, the function of the torch generating plasma plays an important role. In general, a material is melted using a thermal plasma, and a DC arc plasma torch or a cavity type torch is usually used.

The cavity type plasma torch is composed of an electrode that generates a DC arc inside, and this electrode is formed of a front electrode and a rear electrode to move to the object to be melted while focusing the plasma, which is an ultra-high temperature conductive fluid. This easy-to-focus plasma frame makes it easy to operate the plasma frame while increasing the power.

However, when arcs focused through the front electrode are discharged to the outside, side arcing, which is a non-ideal discharge, may occur in the focused arc depending on the properties of the molten material. Side arcing is a factor that damages the cooling channel of the torch or increases the loss of internal electrodes by contacting the plasma frame with the body of the torch, thereby eroding operation instability and torch life.

To solve this problem, a protruding nozzle made of graphite material is attached to the front electrode of the torch to prevent side arcing, but abnormal discharge to a bolt or nut to fix the nozzle to the torch body, fixing by high temperature Many difficulties in operating the torch have arisen due to the loss of the screw and the occurrence of a separation distance from the melt due to the protruding nozzle.

In addition, the nozzle attached to the front electrode has the advantage that the arc point is concentrated inside when plasma is generated as the front electrode is extended, but when side arcing occurs in the torch body, it affects the internal front electrode, making the plasma frame unstable It became a factor. In addition, since the heat transferred to the front electrode was transferred to the torch body through the contacted nozzle, the cooling efficiency was degraded and the cooling channel was damaged.

Korean Patent Publication No. 10-1629683

The present invention is conceived to solve the above-described problem,

An object of the present invention is to provide a plasma torch with improved durability by preventing side arcing that occurs during operation of the plasma torch.

The object of the present invention is not limited to the objects mentioned above, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

The characteristics of the present invention for achieving the object of the present invention as described above and performing the characteristic functions of the present invention described later are as follows.

A hollow rear electrode having a closed end and an open end on one side and the other side, respectively; A hollow front electrode having an inlet and an outlet, and disposed coaxially with the rear electrode so that the inlet faces the open end of the rear electrode at a predetermined distance; A gas supply port forming a flow path to introduce a reaction gas for generating plasma into an internal reaction space of the rear electrode and the front electrode through a gap between the rear electrode and the front electrode; And a hollow outer body having a diameter and a length sufficient to accommodate the rear electrode, the front electrode, and the gas supply port, and receiving the rear electrode, the front electrode, and the gas supply port therein, and the front electrode. The electrode is insulated from the external body by an insulating material, and the insulating material is glass wool.

Preferably, the outer body is provided with a flat carbon cover at an outer end thereof, wherein the carbon cover is spaced apart from the front electrode.

In addition, the outer body is characterized in that the carbon cover, the inner circumferential surface of the outer body, and the front electrode form a space therein, and a glass wool is embedded in the space to perform an insulating function.

In addition, the carbon cover is characterized in that it is provided detachably.

In addition, the cavity type plasma torch further includes a cooling channel therein, wherein the cooling channel includes: a first cooling channel provided in the front electrode to independently cool the front electrode; And a second cooling channel provided in the outer body to independently cool the outer body.

As described above, according to the planar carbon cover provided at the end of the outer body of the present invention, the effect of reducing side arcing generated at the end of the front electrode is provided.

The effects of the present invention are not limited to those described above, and other effects not mentioned will be clearly recognized by those skilled in the art from the following description.

1 is a cross-sectional view of a plasma torch provided with a guide-type front electrode for driving a non-transfer-type torch according to an embodiment of the present invention.
2 is a cross-sectional view of a guide-type front electrode according to an embodiment of the present invention.
3 is a configuration diagram of a guide-type front electrode according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings. It should be noted that the same elements in the drawings are indicated by the same reference numerals wherever possible. In addition, descriptions of known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

In addition, various changes may be made to the embodiments described below. The embodiments described below are not intended to be limited to the embodiments, and should be understood to include all changes, equivalents, or substitutes for them.

It will be logically described below according to the drawings.

1 is a cross-sectional view of a plasma torch provided with a guide-type front electrode for driving a non-transfer-type torch according to an embodiment of the present invention. 2 is a cross-sectional view of a guide-type front electrode according to an embodiment of the present invention. 3 is a configuration diagram of a guide-type front electrode according to an embodiment of the present invention.

1 to 3, a plasma torch equipped with a guide-type front electrode for driving a non-transfer-type torch according to an embodiment of the present invention includes a front electrode 100, a rear electrode 200, and a gas supply. It includes a port (not shown) and an outer body 300.

The rear electrode 200 may have a closed end and an open end on one side and the other side, respectively, and may have a hollow hollow tubular shape.

The front electrode 100 may have an inlet and an outlet, and may have a hollow tubular shape disposed coaxially with the rear electrode 200 so that the inlet faces the open end of the rear electrode 200 at a predetermined interval. Both ends are open, but an arc flame is generated at one end of the rear electrode 200, and the generated plasma is discharged to the outside at the other end of the outlet side.

The gas supply port is a flow path formed so that a reaction gas for plasma generation can be introduced into the internal reaction space of the rear electrode 200 and the front electrode 100 through the gap between the rear electrode 200 and the front electrode 100 Is defined as The reaction gas is transferred from a gas supply source formed outside the plasma torch and supplied between the front electrode 100 and the rear electrode 200 to generate an arc column.

The external body 300 has a diameter and length sufficient to accommodate the rear electrode 200, the front electrode 100, and the gas supply port, and the rear electrode 200, the front electrode 100, and the gas supply port It may be a hollow housing to accommodate the inside. An opening is formed at one end of the outer body to communicate with the outlet of the front electrode 100, through which a plasma flame can be discharged to the outside.

The front electrode 100 may be accommodated in the outer body 300 and may be disposed while forming a constant distance from the outer body 300. At this time, the front electrode 100 is insulated from the external body 300 by the insulating material 150. The insulating material 150 fills the gap between the outer body 300 and the front electrode 100 so that the outer body 300 and the front electrode 100 do not form a conductive channel. Considering that the general shape of the front electrode 100 is cylindrical, the insulating material 150 may have a structure surrounding the outer peripheral surface of the front electrode 100 with a predetermined thickness.

The insulating material 150 is preferably made of glass wool. However, such an embodiment is not enforced, and a known insulating material 150 resistant to high temperatures may be used within a range that can be changed and applied by a person skilled in the art.

A region of the external body 300 close to the outlet side of the front electrode 100 is defined as an end of the external body. At this time, during the operation of the plasma torch, the end of the outer body may be exposed to high temperatures, and thus, damage to the cooling channel flowing along the outer body 300 continuously occurs.

In addition, the front electrode 100 may be uneven due to plasma circulation. When the unevenness occurs at the end, the current is concentrated in the uneven portion, so that the front electrode 100 is oriented toward both sides based on the longitudinal direction of the front electrode 100. A side arcing phenomenon in which the plasma flame spreads occurs, which also causes a high temperature effect on the outer body 300.

In addition, in the process of operating the plasma torch, when the melt in a high temperature state is adsorbed to the front electrode 100, a conductive channel may be formed between the outer body 300 and the front electrode 100, which is 300) is another cause of high temperature effect.

Therefore, in order to prevent this phenomenon, an embodiment of the present invention is provided with a carbon cover 335 at the end of the outer body to protect the outer body 300 from the influence of high temperature.

The carbon cover 335 is a flat structure and is fastened to the end of the outer body. It is preferable that the structure is arranged so as not to protrude in the longitudinal direction of the outer body 300 in the fastened state, but to match the cross section perpendicular to the axial direction of the outer body 300. The carbon cover 335 is disposed to be spaced apart from the front electrode 100. Under this structure, a space 250s defined by the carbon cover 335, the front electrode 100, and the outer body 300 may be formed inside the outer body 300. More specifically, a certain space 250s is defined by an inner surface of the carbon cover 335, an outer peripheral surface of the front electrode 100, and an inner peripheral surface of the outer body 300. The space 250s may be filled with an insulating material 150, and the insulating material 150 is more preferably made of glass wool.

The carbon cover 335 is detachably fastened to the outer body 300 in that it is easily worn as a configuration that is directly affected by the high temperature effect of the operation of the plasma torch. A separate fastening groove may be formed in the carbon cover 335 so that the plasma torch can be easily replaced from the outside without disassembling. The operator can fasten the carbon cover 335 to the outer body 300 by bolting to the fastening groove. Accordingly, a thread corresponding thereto may be formed on one side of the outer body 300.

The carbon cover 335 does not necessarily have to be made of one body, and a plurality of parts may be sequentially bonded along the ends of the outer body. However, in this case, it is preferable to form a through hole in the center so that the end of the outer body is not exposed to the outside, and the plasma flame can be emitted from the outlet of the front electrode 100. Therefore, the carbon cover 335 may have a shape such as a circular ring in a fastened state.

In addition, there is a cooling channel inside the plasma torch, which can be divided into three zones.

The first cooling channel 371 is provided on the front electrode 100 so that the front electrode 100 is independently cooled, and the second cooling channel 372 is an external body ( 300). Cooling fluid circulates through each cooling channel to prevent the plasma torch from overheating.

In addition, the front electrode 100 may control a plasma vortex by providing a plurality of ring-type magnets coaxially disposed therein to form a constant magnetic field.

Due to this structural feature, there is an advantage of not only maintaining operation stability and electrode life of the plasma torch, but also blocking risk factors due to side arcing. Therefore, thanks to the front electrode buried inside the torch, it is easy to protect the electrode from molten material and is advantageous for stable non-transfer operation.

The following is a disclosure of configurations including the technical features of the present invention.

A hollow rear electrode having a closed end and an open end on one side and the other side, respectively; A hollow front electrode having an inlet and an outlet, and disposed coaxially with the rear electrode so that the inlet faces the open end of the rear electrode at a predetermined distance; A gas supply port forming a flow path to introduce a reaction gas for generating plasma into an internal reaction space of the rear electrode and the front electrode through a gap between the rear electrode and the front electrode; And a hollow outer body having a diameter and a length sufficient to accommodate the rear electrode, the front electrode, and the gas supply port, and receiving the rear electrode, the front electrode, and the gas supply port therein, and the front electrode. The electrode is insulated from the external body by an insulating material, and the insulating material is glass wool.

Preferably, the outer body is provided with a flat carbon cover at an outer end thereof, wherein the carbon cover is spaced apart from the front electrode.

In addition, the outer body is characterized in that the carbon cover, the inner circumferential surface of the outer body, and the front electrode form a space therein, and a glass wool is embedded in the space to perform an insulating function.

In addition, the carbon cover is characterized in that it is provided detachably.

In addition, the cavity type plasma torch further includes a cooling channel therein, wherein the cooling channel includes: a first cooling channel provided in the front electrode to independently cool the front electrode; And a second cooling channel provided in the outer body to independently cool the outer body.

On the other hand, the present invention is not limited by the embodiments of the present invention and the accompanying drawings in the above description, and it is apparent to those skilled in the art that various substitutions, modifications and changes are possible within the scope of the technical spirit of the present invention. something to do.

Front electrode 100
Rear electrode 200
Gas supply port 400
External body 300
Cooling gas line 160
Insulation 150
Carbon Cover 335
Space 250s
1st cooling channel 371
2nd cooling channel 372

Claims (5)

A hollow rear electrode having a closed end and an open end on one side and the other side, respectively;
A hollow front electrode having an inlet and an outlet, and disposed coaxially with the rear electrode so that the inlet faces the open end of the rear electrode at a predetermined distance;
A gas supply port forming a flow path to introduce a reaction gas for generating plasma into an internal reaction space of the rear electrode and the front electrode through a gap between the rear electrode and the front electrode; And
Includes; a hollow outer body having a diameter and length sufficient to accommodate the rear electrode, the front electrode, and the gas supply port, and receiving the rear electrode, the front electrode, and the gas supply port therein,
The front electrode,
Insulated from the outer body by an insulating material,
The insulating material,
Plasma torch provided with a guide-type front electrode for driving a non-transfer torch, characterized in that the glass wool.
The method of claim 1,
The external body,
A plasma torch provided with a guide-type front electrode for a non-transfer-type torch operation, wherein a flat carbon cover is provided at an outer end, the carbon cover is spaced apart from the front electrode.
The method of claim 2,
The external body,
A guide-type front electrode for a non-transfer-type torch operation, characterized in that the carbon cover, the inner circumferential surface of the outer body, and the front electrode are formed inside, and a glass wool is embedded in the space to perform an insulating function Plasma torch equipped with this.
The method of claim 3,
The carbon cover,
Plasma torch provided with a guide-type front electrode for driving a non-transfer torch, characterized in that it is detachably provided.
The method of claim 4,
The cavity type plasma torch,
Further including a cooling channel therein,
The cooling channel,
A first cooling channel provided in the front electrode to independently cool the front electrode; And
Plasma torch provided with a guide-type front electrode for driving a non-transfer torch including; a second cooling channel provided in the external body to independently cool the external body.

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