KR20240024879A - The tungsten electrode - Google Patents

Abstract

The present invention relates to a tungsten electrode that generates a plasma arc, and more specifically, to a tungsten electrode in which tungsten that generates an arc and an electrode body that conducts electricity are integrally joined in a vacuum furnace with a silver brazing material.
In the present invention, in constructing a tungsten electrode, an internal hole (4) and an electrode body extension (5) are formed in the electrode body (2), so that the silver brazing material (3) melts during vacuum brazing to form the internal hole of the electrode body (2). A tungsten electrode is constructed so that the silver brazing material (3) overlaps (9) on the electrode body extension (5), which extends below the electrode body (2) through (4), so that the silver brazing material (3) does not flow down. There is a characteristic in that.

Description

Tungsten electrode {THE TUNGSTEN ELECTRODE}

The present invention relates to a tungsten electrode that generates a plasma arc, and more specifically, to a tungsten electrode in which tungsten that generates an arc and an electrode body that conducts electricity are integrally joined in a vacuum furnace with a silver brazing material.

In general, the plasma spraying device, which is widely used in shipbuilding, automobiles, textiles, railways, aerospace, energy industry, steel, and non-ferrous industries, has an electrode and a coat surrounding the electrode, insulates the electrode and the coat, and provides a plasma gas inlet. It consists of a main torch and a secondary torch having an insulator.

The tungsten electrode used in thermal spraying, semiconductor, and waste gas decomposition electrode fields is an electrode that generates a plasma arc. It is composed of positive and negative ions, electrons, excited neutrons, and molecules between the tungsten electrode and the nozzle, and is heated to a high temperature. generates a plasma arc.

Information on such plasma spraying devices and the like can be found in the references described below.

In Reference 1; A main torch having a first electrode having a spraying material discharge hole, a first coat, and a first insulator having a first plasma gas inlet, a second electrode, a second coat, and a second plasma gas inlet. It is provided with a secondary torch having a second insulator, wherein the first electrode and the second electrode melt the spraying material supplied from the spraying material discharge hole at the center of the axis of the plasma formed on the central axis of the first electrode. A device is disclosed.

In references 2 and 3; Disclosed are electrodes and coolant tubes for a fluid cooled plasma arc torch that help reduce electrode wear to preserve electrode life and minimize the effects of misalignment.

In reference 4; The electrode is made up of a cylindrical tube having an internal space of a first part and a second part into which the refrigerant is injected, and first and second paths that provide a refrigerant movement path to the first part and the second part, thereby improving cooling efficiency. A plasma torch with improved cooling efficiency that can be used for a long time and can apply high voltage is disclosed.

In reference 5; A plasma arc torch is disclosed in which a coolant pipe with a coolant passage is disposed inside an electrode holder.

Conventional tungsten electrode manufacturing technology is a method of melting silver brazing material on the side of the tungsten and combining tungsten and the electrode body. It is manufactured by processing it into a flat surface without forming the electrode body and combining the tungsten metal surface and the electrode body surface. As tungsten is cooled indirectly, cooling efficiency decreases, and as a result, defects occur at the interface between tungsten and the electrode body, making interfacial separation easy and causing various problems such as a significant decrease in electrode lifespan.

Therefore, the conventional technology has problems such as low cooling efficiency due to indirect cooling in indirect contact with the coolant, and bonding defects occur at the interface, which facilitates interface separation and limits the lifespan of the electrode.

(Reference 1) Republic of Korea Patent Publication No. 10-2015-0133849, 2015.11.30. (Reference 2) Republic of Korea Patent Publication No. 10-2009-0032125, 2009.03.31. (Reference 3) Republic of Korea Patent Publication No. 10-0940385, 2010.02.02. (Reference 4) Republic of Korea Patent Publication No. 10-2011-0118314, 2011.10.31. (Reference 5) Japanese Open Utility Model Publication No. 6-66876, September 20, 1994.

The present invention seeks to provide a significantly improved tungsten electrode that prevents interfacial separation and has excellent cooling efficiency by combining tungsten, which generates an arc, and an electrode body, which conducts electricity, in a single piece with a silver brazing material in a vacuum furnace.

Looking at this more specifically,

The tungsten electrode that generates the plasma arc uses high current, so most water-cooled electrodes are used. Since cooling is important for tungsten electrodes, coolant enters the electrode body to cool the heat generated when arc occurs. Therefore, in order to extend the life of the electrode, the tungsten must be configured to be directly exposed to the coolant.

Accordingly, the present invention solves the problem of the conventional manufacturing method, which is the problem that the bonding surface of the tungsten (1) and the electrode body (2) is joined in a flat plane, and bonding defects frequently occur at the bonding surface, and the problem of the cooling water inside the electrode body (2). In order to improve the problem caused by indirect cooling of tungsten (1) (see Figures 5 and 6), an internal hole (4) is formed in the electrode body (2) so that tungsten (1) (8) can be cooled directly. We would like to provide electrodes.

The present invention for solving the above problems;

In a high vacuum furnace, at the brazing temperature of the silver brazing material, the silver brazing material seeps into the gap between the electrode body and the tungsten, thereby combining the electrode body metal and the arc-generating metal to form a tungsten electrode.

The present invention is a tungsten electrode that generates a plasma arc. It provides a technology for manufacturing a tungsten electrode by integrally combining the tungsten that generates the arc and the electrode body that conducts electricity in a vacuum furnace with a silver brazing material, which is better than the existing manufacturing method. We can provide significantly improved technology and superior products by extending the life of electrodes, eliminating bonding defects, and increasing cooling efficiency.

1 to 2 are cross-sectional views showing one embodiment of the present invention.
3 to 4 are cross-sectional views showing another embodiment of the present invention.
5 to 6 are cross-sectional views showing the conventional structure.

The present invention is characterized by constructing a tungsten electrode by allowing the silver brazing material to seep into the gap between the electrode body and the tungsten at the brazing temperature of the silver brazing material in a high vacuum furnace and combining the electrode body metal and the arc generating metal.

Hereinafter, specific implementation details of the present invention will be examined in detail along with the accompanying drawings.

Figures 1 and 2 are cross-sectional views showing one embodiment of the present invention, and Figures 3 and 4 are cross-sectional views showing another embodiment of the present invention.

Among the symbols used in the drawings, the same symbols are used for components that are the same as those in the conventional configuration (FIGS. 5 and 6).

The present invention relates to a tungsten electrode that generates a plasma arc. The tungsten electrode (1) that generates the arc and the electrode body (2) that conducts electricity are integrally combined in a vacuum furnace with a silver brazing material (3) to form a tungsten electrode. constitutes.

Looking at this more specifically; In a high vacuum furnace, at the brazing temperature of the silver brazing material (3), the silver brazing material (3) seeps into the gap (10) of the two metals between the electrode body (2) and the tungsten (1), and the electrode body (2) and the arc-generating metal tungsten Combine (1).

And, as shown in Figures 3 and 4, an arc-generating metal tungsten (8) with a protruding shape (6) that penetrates and is coupled to the inner hole (4) of the electrode body (2) is formed and joined.

Let’s look at this in more detail.

The inner hole 4 is formed in the electrode body 2 so that the silver brazing material 3 inside the electrode body 2 is melted into the tungsten 1, which generates an arc, and joined as shown in FIG. 2.

An internal hole (4) is formed inside the electrode body (2) as shown in FIGS. 1 and 2, so that the silver brazing material (3) is melted, combined with the tungsten (1), and protrudes inside the electrode body (2).

In addition, as shown in FIGS. 3 and 4, tungsten 8 is formed in a protruding shape 6 by being inserted into and coupled to the inner hole 4 of the electrode body 2.

In other words, the tungsten (8) is configured to be combined in a protruding shape (6) inside the electrode body (2) to increase the interfacial area where the tungsten (8) is joined to the electrode body (2), thereby electrically and coolingly protecting the tungsten electrode. Lifespan can be improved.

In addition, during vacuum brazing, the silver brazing material (3) melts and overlaps (9) the silver brazing material (3) on the electrode body extension (5) extending below the electrode body (2) through the inner hole (4) of the electrode body (2). : the part that comes together) and is designed to prevent the silver brazing material (3) from flowing down.

As shown in Figures 1 to 4, an internal hole 4 is formed in the electrode body 2 to increase the contact area with the electrode body 2, thereby improving electrical and cooling efficiency by improving direct cooling, unlike the conventional structure of indirect cooling. We can provide this excellent tungsten electrode.

In addition, when joining the two metals, tungsten (1,8), and the electrode body (2), the silver brazing material (3) melts and penetrates through the gap (10) of the two metals, so the rate of occurrence of bubbles or defects is low and the electrode body (2) is The tungsten (1, 8) is directly exposed through the internal hole (4), which increases cooling efficiency and significantly improves electrode life.

In order to specifically explain the implementation of the present invention, the symbols used in the accompanying drawings are explained as follows.
1: Tungsten 2: Electrode body
3: Silver brazing material 4: Internal hole
5: Electrode body extension 6: Protruding shape
7: Space where silver solder permeates 8: Tungsten
9: Silver soldering material overlap (where silver soldering materials gather) 10: Gap between two metals

Claims (1)

An internal hole (4) and an electrode body extension (5) are formed in the electrode body (2), so that during vacuum brazing, the silver brazing material (3) melts and passes through the internal hole (4) of the electrode body (2) to the electrode body (2). ) A tungsten electrode characterized in that the silver brazing material (3) overlaps (9) with the expanded portion of the electrode body (5) below, thereby preventing the silver brazing material (3) from flowing down.

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