KR20010037439A - A plasma gun device for the injection of strengthening-powder - Google Patents

Abstract

PURPOSE: A plasma gun for jetting powder-reinforcing materials is provided to enhance the output voltage of the plasma jet, and reduce the amount of powder scattered over the outside when the reinforcing powder is injected to a melt bath or is coated onto parent materials. CONSTITUTION: A plasma gun comprises a positive electrode nozzle(1) wrapped in a nozzle shell(2), a negative electrode(6) installed at the same interval on the inlet of the nozzle(1), a holder(7) for holding the negative electrode(6), a nut(5) for combining the electrode(6) with an electrode holder(7), an insulator(4) for insulating the electrode from positive electrode, and a water channeling head(3) having a passage(12) for passing cooling water. To supply the reinforcing powder through the nozzle(1), a powder supplier(9) is extend from the outside of the water channeling head(3) to the inside of the nozzle(1) at predetermined angle in respect to the jet direction. In the side of the insulator(4) are many holes for passing gas. Many sloping grooves(11) are formed in the outside of the nut(5).

Description

A plasma gun device for the injection of strengthening-powder

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma gun apparatus for spraying powder reinforcement materials, and more particularly, to a plasma gun apparatus for spraying a metal powder or a base metal by using a high-temperature, high-speed plasma jet generated from the inside. It is about.

In order to improve the properties of metals and alloys, alloys prepared by incorporating metal powders or ceramic powders, which are reinforced particles, into a metal matrix are called metal base composites. . For example, titanium, zirconium, manganese, etc., which have a high melting point, may be added to an aluminum alloy, or different types of ceramic particles (such as SiC, Al ₂ O ₃ ) in pure metals and alloys (aluminum, magnesium, titanium, copper, etc.) may be used. And a composite material prepared by forcibly mixing and uniformly dispersing in the matrix of the molten metal.

As one of the methods for manufacturing a metal base composite material, there is a high-speed gas generated by arc discharge to make a gas into a plasma state, and high-speed injection of powder-reinforced particles into the molten base metal.

In addition, this method is also applied to a thermal spraying technique in which reinforcing particles are sprayed onto a base material by using plasma.

In particular, since the generated plasma has a high energy source of nearly 20,000 ° K, a wider variety of reinforcing materials such as high melting point metal powder and ceramic powder can be injected and sprayed.

3 shows a conventional plasma gun apparatus for generating such plasma arcs and plasma jets.

The structure of the device is largely composed of a nozzle 1, a nozzle shell 2, an electrode 6, an insulator 4, an electrode holder 7 and a nut. ), A water channeling head (3), a powder feeder (9) and a support (8). In the front part of the insulator 4, the hole for a plasma gas to pass through is formed.

The nozzle 1 in which the plasma jet is generated belongs to the anode portion together with the nozzle cover 2. Moreover, the electrode 6 which is a cathode part is provided in the inlet part of the nozzle 1, maintaining a fixed space | interval.

On the other hand, when an arc is generated between the nozzle 1 and the electrode 6 while blowing a gas for plasma such as argon (Ar) or nitrogen (N ₂ ), the gas is dissociated by the high heat generated at this time. Jet is formed. This high temperature, high speed plasma jet is injected through the nozzle 1 inlet to the outlet. At this time, since the anode spot at which the arc of the inner wall of the nozzle 1 is generated becomes very high, the coolant flows along the passage 12 formed in the water channeling head 3 and the nozzle cover 2. It is supposed to cool.

Here, a difference in the output voltage is generated according to the position of the anode point inside the nozzle 1 in which the arc is generated. As the distance between the electrode and the anode point increases, the voltage increases and the output of the plasma jet is increased.

The electrode body electrically belonging to the cathode part is composed of an electrode 6, an electrode holder 7 and a nut 5, the electrode 6 being fixed by an electrode holder 7 in the rear part and having a nut 5. As a result, the electrode 6 and the electrode holder 7 are integrally fastened. The outside of the electrode body is insulated from the anode portion by a hollow cylindrical insulator 4 made of ceramic.

At the outermost side, the water channeling head 3 for cooling the entire plasma gun is installed in the form of connecting the electrode bodies 5, 6, 7 wrapped in the insulator 4 and the nozzle 1, and the cooling water passage ( 12) is formed in the spraying direction.

The supply gas is supplied between the insulator 4 and the water channeling head 3 and passes between the electrode 6 and the nozzle 1 inner surface through a hole penetrated in front of the insulator 4 to react with the arc to generate a plasma jet. Will be.

The powder supply device 9 is installed outside the front of the nozzle 1 via the support 8. When the reinforcing powder is supplied through the powder supply device 9, the powder encounters a high temperature, high speed plasma jet from the nozzle 1 inlet. As such, the reinforcement powder is loaded into the plasma jet at high speed or injected into the molten metal (not shown).

Here, in order to easily inject the reinforcing particle powder into the molten metal or to form a solid film on the surface of the base metal, the kinetic energy (½mv ² , m is the mass of the powder and v is the speed of the powder) and the heat transfer of the injected reinforcing particles are required to be large. .

However, in the conventional plasma gun apparatus as shown in Fig. 3, since the powder supply device 9 is mounted outside the nozzle 1, where the velocity and energy of the plasma jet are weak and unstable, In addition to poor heat transfer, the kinetic energy is weak and the powder is easily scattered in the other direction, so it is difficult to easily add the coating to the molten metal or to firmly coat the coating on the base metal.

In order to solve this problem, the energy of the plasma jet may be increased by additionally using molecular gases such as nitrogen, oxygen, and hydrogen as a secondary gas to improve the output voltage. Other problems have arisen, including increased manufacturing costs and complicated gas supply equipment.

The present invention has been made to solve the above problems, an object of the invention is to supply the reinforcing material powder inclined at an appropriate position inside the nozzle and injected while rotating the gas for plasma, thereby increasing the output of the plasma jet of the powder to be injected In addition to increasing kinetic energy and facilitating heat transfer, it also prevents scattering of the powder to be sprayed, thereby making it easy to enter the molten metal and to form a solid film to the base metal.

1 is a side cross-sectional view showing a plasma gun device according to the present invention,

Figure 2 is a diagram showing the comparison, the output voltage for the gas flow rate in the present invention and the conventional plasma gun device,

3 is a side cross-sectional view showing a conventional plasma gun device.

<Explanation of drawing code>

1 ... nozzle 2 ... nozzle shell

3 ... water channeling head

4 ... insulator 5 ... nut

6 ... electrode 7 ... electrode holder

8 ... powder feeder support 9 ... powder feeder

10 ... insulator hole 11 ... nut surface groove

12. Coolant passage

In order to achieve the above object, the present invention includes an anode nozzle wrapped by a nozzle cover; A cathode part electrode installed at a predetermined interval at an inlet of the nozzle; A holder for fixing the electrode from the rear side; A nut for integrally coupling the electrode and the electrode holder; An insulator surrounding the electrode, the electrode holder and the nut to insulate the electrode from the anode portion; In the plasma gun device consisting of a water channeling head is formed for passage of the cooling water passages,

The powder supply device is formed to be inclined with respect to the spray direction axis from the outer surface of the water channeling head to the inner surface of the nozzle so that the reinforcing powder is supplied through the nozzle 1 with a part of the inner surface protruding therefrom. A plurality of holes through which the plasma gas passes in the circumferential direction is formed at the connection portion of the electrode holder, and the outer surface of the nut is formed with a plurality of grooves inclined with respect to the injection direction axis.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

A plasma gun apparatus according to the present invention is shown in FIG. 1. The description of the parts corresponding to the above-described conventional plasma gun apparatus will be omitted, and only key features will be described as follows.

In the conventional plasma gun, the plasma gas is supplied to the arc generating region through the hole 10 formed in front of the insulator 4, but in the present invention, the plasma gas is a part where the electrode holder 7 and the nut 5 are connected. A hole 10 is formed in the insulator 4 so as to be supplied. Here, the nut 5 only serves to couple the electrode 6 and the electrode holder 7, but in the present invention, a predetermined size in which a slope is formed at a predetermined angle with respect to the axis of the spray direction on the surface of the nut 5. The gas 11 which cuts out the groove | channel 11 of and passes through can rotate in a vortex form. As a result, the distance between the electrode 6 and the anode point on the inner surface of the nozzle 1 in which the arc occurs becomes longer and the length of the arc becomes longer, resulting in an effect of increasing the output voltage. As a result, the output of the plasma jet is increased to increase the kinetic energy of the powder to be injected and to facilitate heat transfer.

In addition, although the diameter of the inner surface of the nozzle 1 is conventionally maintained, the nozzle 1 according to the present invention has a portion protruded inward, thereby reducing the inner diameter A, thereby increasing the flow rate of gas.

The powder supply device 9 for supplying powder inclines the hole from the outer surface of the water channeling head 3 to the arc generating region inside the nozzle 1 with the highest temperature, high speed and low turbulent flow of plasma. It is formed by extending. Due to this, the reinforcing powder is made easy to heat transfer, the kinetic energy is increased and scattering is prevented.

The spraying process of the reinforcement powder is as follows.

As shown in FIG. 1, a plasma gas is blown between the insulator 4 and the water channeling head 3 to flow through the hole 10 formed in the insulator 4. The gas thus passed flows along the inclined groove 11 formed on the surface of the nut 5 and rotates about the spray direction axis. Next, as soon as the gas passes through the portion having the minimum inner diameter A, an arc is generated between the nozzle 1 and the electrode 6, and the plasma gas dissociates the plasma gas through which high heat passes by the arc. To form.

At the same time, when the reinforcing powder is supplied to the arc generating region in the nozzle 1 through the powder supply device 9, the powder is loaded on the plasma jet and sprayed on the molten metal or the base material through the nozzle 1 outlet. At this time, since the plasma jet is high temperature and high speed, when the plasma jet is introduced into the molten metal, the plasma jet is more easily mixed, and when sprayed onto the base material, a more robust film can be formed.

In Fig. 2, an experimental result of comparing the output voltage according to the configuration difference between the plasma gun of the present invention configuration and the conventional plasma gun as shown above is shown.

The maximum output of the plasma generator used in this experiment is 40 kW. In the case of the nozzle 1, the inner diameter A of the nozzle 1 of the conventional plasma gun apparatus is 6.3 mm, and the nozzle 1 of the plasma gun apparatus of the present invention is partially protruded inward so that the minimum inner diameter A is Is 4.5mm. In the conventional apparatus, two holes of 2 mm diameter are formed in the insulator 4 at the front of the nut 5 so that the supply gas flows directly to the nozzle 1, but in the apparatus of the present invention, the nut 5 and the electrode holder 7 4 holes with a diameter of 1.6 mm were formed at the connection points of Here, the nut 5 of the apparatus of the present invention is formed with a groove 11 having a 45 ° inclination as a thread having a height of about 1 mm, so that the supplied gas can flow in the arc generating region while rotating.

In the water channeling head 3 of the prior art and the present invention, six cooling water passages 12 having a diameter of 3.5 mm are sequentially formed. However, in the present invention, a hole having a diameter of 1.6 mm extending from the powder supply device 9 at an intermediate position of the coolant passage 12 is inclined to the inner surface of the nozzle 1.

As shown in FIG. 2, when argon (Ar) is used as the primary gas without using the secondary gas in the plasma generator having a maximum output of 40 kW, the gas flow rate is used at each of the operating currents of 300, 400, and 500 A. FIG. The variation of the output voltage can be seen. As shown, it was found that the output voltage of about 20 to 35% was increased compared to the conventional plasma gun for the same gas flow rate. That is, since the output of the plasma jet is improved by that much, it means that the kinetic energy of the powder can be increased and added to the molten metal.

According to the present invention having the above-described configuration, the output voltage of the plasma jet can be improved only by the primary gas, thereby reducing the manufacturing cost, and supplying the powder to the molten metal by inclining the powder into the plasma gun. When added or applied to the base material, not only increases the speed of the powder, but also can reduce the amount of scattering to the outside, there is an advantage that it is possible to precisely control the volume fraction of the predetermined reinforcing material and maintain the coating amount more firmly.

Claims (1)

The anode part nozzle 1 wrapped by the nozzle cover 2, the cathode part electrode 6 which is provided in the inlet of this nozzle 1 at predetermined intervals, and the holder which fixes this electrode 6 from the back side ( 7), a nut 5 for integrally coupling the electrode 6 and the electrode holder 7, the electrode 6, the electrode holder 7 and the electrode 6 to insulate the electrode 6 from the anode portion; In the plasma gun apparatus composed of an insulator (4) surrounding the nut (5) and a water channeling head (3) having a passage (12) through which cooling water passes for cooling, The powder supply device 9 is formed to be inclined with respect to the injection direction axis from the outer surface of the water channeling head 3 to the inner surface of the nozzle 1 so that the reinforcing powder is supplied through the nozzle 1 with a part of the inner surface protruding therefrom. The side of the insulator 4 is formed with a plurality of holes through which the plasma gas passes in the circumferential direction at the connection portion between the nut 5 and the electrode holder 7, and on the outer surface of the nut 5 an injection direction shaft. Plasma gun apparatus for spraying powder reinforcement, characterized in that a plurality of grooves 11 are inclined with respect to.