KR20210003470A - Low power plasma arc torch electrode assembly - Google Patents

Abstract

According to the present invention, disclosed is a low-power arc torch electrode, which comprises: an electrode body unit to which a plasma nozzle is coupled to an end while being grounded; an electrode tip unit provided inside the electrode body unit, and positioned adjacent to a discharge port of the plasma nozzle; and a whirlwind forming unit for generating whirlwind in a reaction gas supplied into the plasma nozzle. A groove unit is formed in the discharge port of the plasma nozzle to improve the discharge area with the electrode tip unit. According to the present invention, the plasma nozzle and the electrode tip unit are positioned close to each other to allow discharge even at a lower voltage and to form the groove unit at the discharge port of a nozzle, such that the discharge area of the electrode tip unit is improved to have excellent discharge efficiency. In addition, whirlwind is generated in the reaction gas through the whirlwind forming unit to allow air to be rotated and discharged even when discharge is only partially instantaneously generated, such that discharge gas is not biased or partially discharged gas is not emitted, but uniform plasma discharge gas is supplied.

Description

Low power arc torch electrode {LOW POWER PLASMA ARC TORCH ELECTRODE ASSEMBLY}

The present invention relates to a low power arc torch electrode, and more particularly, to an arc torch electrode capable of discharging even at a low voltage and capable of supplying a uniform discharge gas.

In general, plasma arc torches are widely used for cutting metal materials, and torch body, electrodes mounted in the body, nozzles having a central outlet orifice, electrical connections, passages for cooling and arc control fluids, and control of flow path patterns. It is a configuration including a swirl ring for, and a power supply.

The gas used in the torch can be non-reactive (e.g., argon or nitrogen), or reactive (e.g., oxygen or air), and the torch is a plasma arc, which is a plasma gas of a limited ionizing jet with high temperature and high momentum. To form.

Here, a technique related to the electrode of the arc torch has been proposed in Korean Utility Model Publication No. 2000-0003214.

However, Patent Document 1 has a problem in that when the distance between the nozzle and the spinning insert is far away, the discharge occurs only by a high voltage, so that the temperature rises during work, and when the discharge occurs only in an instant, the discharge occurs in a biased state.

Korea Open Utility Model No. 2000-0003214 (2000.02.15)

The present invention has been devised in consideration of the above points, and the problem of the present invention is that the plasma nozzle and the electrode tip are placed close to discharge even at a low voltage, and a tornado is generated in the reaction gas to produce a uniform discharge gas. It is an object of the present invention to provide a low-power arc torch electrode to be supplied.

A low-power arc torch electrode according to the present invention for achieving the above object includes: an electrode body portion to which a plasma nozzle is coupled to an end while being grounded; An electrode tip portion provided inside the electrode body portion and having an end portion positioned adjacent to a discharge port of the plasma nozzle; And a tornado forming part for generating a tornado in the reaction gas supplied to the inside of the plasma nozzle, and a groove part may be formed in the discharge port of the plasma nozzle to improve a discharge area with the electrode tip part.

The electrode tip portion may be formed in a private shape or an arc-shaped protrusion may be formed.

The groove may be recessed in an arc shape.

The tornado forming part may be formed in a screw shape.

According to the present invention, the plasma nozzle and the electrode tip are positioned close to each other so that discharge occurs even at a low voltage, and a groove is formed in the discharge port of the nozzle to improve the discharge area with the electrode tip, so that the discharge efficiency is excellent. Even if only a part of the discharge occurs instantaneously by generating a tornado in the gas, the air turns and exits, so there is an effect that the discharge gas is not biased or the gas discharged only partially comes out, but a uniform plasma discharge gas is supplied.

1 is a schematic diagram showing a low power arc torch electrode of the present invention.
2 is a partially enlarged view showing an embodiment of the shape of the plasma nozzle and the electrode tip portion in the low-power arc torch electrode of the present invention.
3 is a plan view showing a tornado formation in the low-power arc torch electrode of the present invention.
4 is a schematic diagram showing a state in which the plasma nozzle portion is provided to adjust the height of the low-power arc torch electrode of the present invention.

The above objects, features and other advantages of the present invention will become more apparent by describing in detail a preferred embodiment of the present invention with reference to the accompanying drawings. Hereinafter, a low-power arc torch electrode according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view showing a low-power arc torch electrode of the present invention, Figure 2 is a partial enlarged view showing an embodiment of the shape of the plasma nozzle and the electrode tip portion in the low-power arc torch electrode of the present invention, Figure 3 is It is a plan view showing a tornado forming part in the low-power arc torch electrode of the present invention, and FIG. 4 is a schematic diagram showing a state in which the height of the plasma nozzle part is adjustable in the low-power arc torch electrode of the present invention.

1 and 3, the low-power arc torch electrode 100 of the present invention includes an electrode body part 110, an electrode part 120, a tornado forming part 130, a gas supply part 140, and a power supply part 150. ).

The electrode body portion 110 is formed in a cylindrical shape having a hollow inside, and has an opening in the lower portion. In this case, the entire electrode body portion 110 may be made of an insulator or only the inner circumferential surface of the electrode body 110 may be made of an insulator.

In addition, a cylindrical ground electrode 112 is provided inside the electrode body portion 110. At this time, the ground electrode 112 is provided so as to surround the electrode unit 120 and is made of tungsten having excellent conductivity and good heat resistance and strength.

Furthermore, the electrode body 110 is coupled to the plasma nozzle 114 at the lower part of the opening, and an inlet 110a for supplying a reactive gas such as air or gas into the electrode body 110 is formed on one side of the outer circumferential surface. .

The plasma nozzle 114 has an orifice formed at an upper end thereof and a discharge port 114a formed at an inner lower end of the plasma nozzle 114 to spray plasma.

The electrode part 120 is located inside the electrode body part 110 so that plasma discharge occurs between the ground electrode 112 when power is applied.

Furthermore, the electrode part 120 is provided with an electrode tip part 122 at the lower end of the plasma nozzle 114 in close proximity to the discharge port 114a. In this way, since the electrode tip portion 122 is provided close to the discharge port 114a of the plasma nozzle 114, discharge is performed even when a low voltage is applied, and the temperature according to the application of the low voltage is reduced. However, when the distance between the electrode tip portion 122 and the discharge port 114a of the plasma nozzle 114 increases, the temperature increases according to application of a high voltage.

Further, the electrode unit 120 is electrically connected to the power supply unit 150 through the electrode body unit 110, and a high or low voltage current can be selectively supplied through the control of a control unit (not shown in the drawing).

Here, the electrode unit 120 is also preferably made of tungsten having excellent conductivity and good heat resistance and strength.

On the other hand, referring to FIG. 2, the electrode tip part 122 has an end portion formed in a private shape (a) or an arc-shaped protrusion (b), and the like, and the corresponding discharge port 114a of the plasma nozzle 114 ) In order to improve the discharge area with the electrode tip part 122, a groove part 116 having a shape such as an arc is formed. This is to increase the discharge area for this, because the discharge efficiency is excellent to cause a lot of discharge to occur near the discharge port 114a of the plasma nozzle 114.

The tornado forming part 130 is formed of a non-conductor and is provided on the electrode body part 110 to generate a tornado in the reaction gas supplied to the inside of the plasma nozzle 114. This creates a tornado in the reaction gas, so that even if only a part of the discharge occurs momentarily, the air turns and exits, so that the discharge gas is not biased or partially discharged gas, but a uniform plasma discharge gas is supplied.

To this end, a plurality of tornado forming holes 132 having a screw shape or different positions (angles) of the inlet and the outlet are radially formed in the tornado forming part 130.

The power supply unit 140 is provided outside and is electrically connected to supply power such as low voltage to the electrode unit 120.

The gas supply unit 150 is externally provided to supply a reactive gas such as argon (Ar), helium (He), or air into the ground electrode 112, and has a pressure sufficient to provide an injection force to the generated plasma. A flow of reactive gas is provided within the ground electrode 112.

Referring to FIG. 4, the plasma nozzle 114 can be adjusted in height. To this end, spiral protrusions 111 and 114b whose spiral directions are opposite to each other are formed on the lower portion of the electrode body portion 110 and the upper portion of the plasma nozzle 114 adjacent to each other, and the lower portion of the electrode body portion 110 and the plasma nozzle It is screwed to the spiral projections (111, 114b) formed on the upper portion of the (114), and the inner circumferential surface is provided with a height adjustment unit 160 forming a spiral hole opposite the spiral direction of both ends.

Therefore, when the height adjustment unit 160 is rotated in any one direction, the electrode tip portion 122 is reduced or widened as the distance between the electrode body 110 and the plasma nozzle 114 spirally fastened to both ends of the height adjustment unit 160 is reduced or widened. ) And the plasma nozzle 114, it is possible to adjust the distance between the discharge port (114a).

Moreover, the upper and lower ends of the electrode body 110 and the plasma nozzle 114 are in close contact with the upper and lower surfaces of the height adjustment unit 160 to prevent loosening while the opposite ends are spirally fastened to the height adjustment unit 160. The loosening prevention parts 62 and 164 are provided.

At this time, the upper and lower anti-loosening parts 162 and 164 are formed in a nut shape in which a spiral hole is formed respectively, and the spiral direction is formed in the opposite direction, so that the spiral protrusion 111 of the electrode body 110 is increased and lowered by the height adjustment unit 160 Is fixed to the upper surface of the plasma nozzle 114, the spiral protrusion 114b of the plasma nozzle 114 is fixed to the lower surface of the height adjustment unit 160.

On the other hand, a groove (G) is formed inside the upper anti-loosening part 162, and a locking part 163 is provided in the groove (G) so as to be rotatable by a hinge axis to adjust the height of the upper anti-loosening part 162 In a state in close contact with the upper surface of the portion 160, the upper locking portion 162 is locked again.

The locking part 163 is formed in a "L" shape, one end is formed in a mountain shape so as to be coupled to the spiral protrusion 111 of the electrode body part 110, and the other end is a groove (G) of the upper loosening prevention part 162 ) Is rotatably supported within. At this time, a torsion spring (S) is installed on the hinge shaft, one end of the torsion spring (S) is supported by the locking portion (163), the other end is supported in the groove (G).

Therefore, when the upper anti-loosening part 162 is in close contact with the upper surface of the height adjustment part 160, one end of the locking part 163 is in contact with the spiral protrusion 111 of the electrode body part 110. (162) to prevent double loosening. On the other hand, although the locking part 163 is illustrated as being installed on the upper anti-loosening part 162, the present invention is not limited thereto and may be installed in the lower anti-loosening part 164 as well.

Moreover, in the present invention, the ground electrode 112, which is an external electrode, surrounds the electrode tip 122 of the electrode part 120, which is an internal electrode, and forms a portion forming a close distance as wide as possible, thereby generating an arc at a lower voltage than the existing one. And, the plasma generated by the arc is prevented from being biased toward one side by passing through the screw-shaped tornado forming part 130 that spirally rotates the reaction gas.

On the other hand, the electrode tip 122 of the electrode part 120, which is an internal electrode, is located inside the ground electrode 112, which is an external electrode, so that the plasma discharged to the plasma nozzle 114 becomes constant only when arc discharge occurs. The closer the 122 is to the entrance of the ground electrode 112, the better the effect of discharging. To this end, the present invention allows the electrode tip part 122 of the electrode part 120 to be located close to the plasma nozzle 114 of the ground electrode 112, and the electrode tip part 122 and the ground electrode 112 to have a large area close to each other. do. In addition, the tornado forming part 130 is positioned above the electrode part 120 so that the supplied reaction gas is rotated and lowered.

In this way, the low-power arc torch electrode 100 of the present invention applies a low voltage to the electrode unit 120 from the power supply unit 150, and the electric field between the electrode tip unit 122 and the ground electrode 112 of the electrode unit 120 In the area, a reactive gas such as air or gas input through the inlet 110a is ionized to generate plasma, and the generated plasma is sprayed to the surface of a work object such as OLED through the outlet 114a to remain on the surface of the object It is possible to remove the crypts.

At this time, since the electrode tip part 122 of the electrode part 120 is provided close to the discharge port 114a of the plasma nozzle 114, discharge occurs even when a low voltage is applied, and the temperature decreases due to the use of the low voltage, which occurs when using a high voltage. A separate cooling device for solving the increase in temperature can be omitted.

Moreover, when the discharge gas introduced through the inlet 110a of the electrode body 110 passes through the tornado forming hole 132 of the tornado forming unit 130, a tornado is generated in the reaction gas, so that a uniform plasma discharge gas is generated. Supply is possible.

In addition, the end of the electrode tip portion 122 is formed in a private shape (refer to FIG. 2(a)), or an arc-shaped protrusion (refer to FIG. 2(b)) is formed, and the corresponding plasma nozzle 114 Since the groove portion 116 having a shape of an arc or the like is formed in the discharge port 114a, a large amount of discharge occurs at the side close to the discharge port 114a of the plasma nozzle 114 through the improvement of the discharge area, and thus discharge efficiency is excellent.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features. You can understand. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not limiting.

100: low power arc torch electrode
110: electrode body
112: ground electrode
120: electrode part
122: electrode tip portion
130: tornado formation
132: tornado formation hole
140: gas supply
150: power supply

Claims (4)

An electrode body portion to which the plasma nozzle is coupled to an end while grounding;
An electrode tip portion provided inside the electrode body portion and having an end portion positioned adjacent to a discharge port of the plasma nozzle; And
Includes; a tornado forming part for generating a tornado in the reaction gas supplied into the plasma nozzle,
A low power arc torch electrode, characterized in that a groove portion is formed at the discharge port of the plasma nozzle to improve a discharge area with the electrode tip portion.
The method of claim 1,
The electrode tip portion is a low-power arc torch electrode, characterized in that the end is formed in a private shape or an arc-shaped protrusion.
The method of claim 1,
The low power arc torch electrode, characterized in that the groove is formed in a concave arc shape.
The method of claim 1,
The low-power arc torch electrode, characterized in that formed in a screw shape of the tornado formation.

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