CS218921B1 - The discharge electrode of the plasma chamber discharge chamber - Google Patents

Abstract

The invention relates to the outlet electrode node of the discharge chamber of a plasmatron. The newly designed outlet node enables the separation of the emerging high-temperature plasma from the peripheral, cooler gas layers. The outlet node consists of a funnel-shaped widening outlet opening in which an annular rectifying segment is slidably placed with a cylindrical inner surface for the discharge of the central part of the gas and with a conical outer surface, the apex of which faces the discharge chamber, while there is a gap between its outer surface and the inner surface of the outlet opening for the discharge of the peripheral, cooler gas layer, and the rectifying segment is controlled by a displacement device for movement in the direction of the longitudinal axis of the discharge chamber.

Description

The invention relates to a new arrangement of an outlet electrode node disposed in the discharge opening of the discharge chamber and separating the emerging high temperature plasma from the peripheral relatively cooler gas layers.

Plasmatrons are devices used to heat the working medium, such as gases and liquids, to very high temperatures. The gas is heated in the discharge chamber, where an electric arc burns between electrodes of different shapes. Due to the intense heat transfer between the arc space, where gas temperatures often exceed 10,000 to 20,000 degrees K and the discharge chamber wall are always considerably larger than the arc diameter. This measure achieves a satisfactory thermal efficiency. The disadvantage, however, is that the bulk of the working gas flows between the arc and the discharge chamber wall and does not participate in heating. In the anode region - ie in the discharge port of the discharge chamber - due to the rapid displacement of the radial portion of the electric arc and the movement of the anode tracks, a portion of the gas flowing through the electric arc and marginal cooler gas flows flowing at the discharge chamber wall are intensively mixed.

Thus, in the case of axial gas flow through the discharge chamber, two concentric parallel currents are mixed, and a direct current flows out of the discharge chamber with velocity and temperature structure, somewhat agitated mixing processes caused by displacement of the anode tracks and adjacent parts of the arc. The mixing also results in lowering the mean temperature of the generated plasma stream and shortening the length of the maximum temperature region. The arc-burning stability of this type of plasmatron is poor and the electrode life is unsatisfactory. A certain improvement is caused by the reduction of the discharge chamber diameter. transition to wall stabilization - but at the expense of so much heat loss that the device is unusable for practical reasons.

Therefore, more often, plasmatrons are used where the working gas is introduced tangentially into the discharge chamber. The tangential supply causes the current field in the discharge chamber to be similar to a potential vortex. The gas flows not only in the direction of the discharge chamber axis, but has a significant tangential velocity component that increases from zero in the discharge chamber axis to the maximum size in close proximity to the wall. The axial component of the discharge velocity in the discharge chamber is approximately constant in the projected arc region and exhibits an increase in value near the wall. Therefore, in the central region, the hot gas, i.e. the plasma, flows approximately in the axial direction, while the cold gas at the wall has a considerable rotational component. Due to the difference in the wall gas and wall plasma densities in the central part, more than half of the total flow mass flows near the wall in close proximity. This method of gas flow is used to improve the stabilization of the arc position in the central portion of the discharge chamber, and this arrangement is often referred to as a vortex stabilization plasmatron.

In this case, too, at the end of the discharge chamber, the mixing of the cold wall gas flowing in the annular space between the wall of the plasmatron and the arc and the hot plasma space flowing in the central part of the discharge chamber occurs. A considerable tangential component of the cold gas causes additional rotation of the hot core, which is reflected both in the structure of the outflowing plasma stream and in the lowering of its mean temperature. Plasma flowing out of the discharge chamber is symmetrical in shape due to vortex stabilization, but the large tangential component of velocity causes the current to have a structure similar to an isothermal free vortex with a short reach of the core and a wide angle of diffusion. the application of a plasma stream in a technology where the greatest possible range of plasma is required, for example when cutting thick materials, and sufficient axial action, especially when applying powdered materials to the surface of the bodies. Said shape of the plasma jet with a large angle of spread causes spraying of the deposited material into the ^! environment and thus losses.

There are other modifications to the introduction and rectification of the working or even auxiliary gas. The purpose of these treatments is, inter alia, to improve the characteristics of the discharge plasma, such as velocity and temperature fields.

Another element that can affect these characteristics is the output electrode, which is typically an anode located at the discharge opening of the discharge chamber. This outlet electrode is predominantly a cylindrical ring which abuts the front surface of the outlet opening. Only the inner wall of the ring comes into contact with the outflowing plasma, which usually aligns with the inner wall of the discharge opening and either maintains the direction of the discharge opening wall or tapers conically or roundly into a nozzle shape whose cone is directed from the discharge chamber. Such an arrangement of the output electrode forces the hottest plasma core to flow unseparated from the peripheral, relatively colder gas layer with which it partially blends, thereby greatly reducing the maximum plasma temperature.

The above-mentioned disadvantages are overcome by the node of the output electrode of the solution according to the invention, characterized in that an annular rectifying segment with a cylindrical inner surface is displaceably disposed in the funnel-widening outlet opening.

With a central gas outlet and a conical outer surface, the apex of which is directed into the discharge chamber, with a gap between the outer surface and the inner surface of the outlet port for evacuating the frigid cooler gas layer, and in the direction of the longitudinal axis of the discharge chamber.

It is highly preferred that at least a portion of the rectifying segment is simultaneously an output electrode.

One possible embodiment is that the outer surface of the rectifier segment and the inner surface of the outlet orifice are flat.

Another possible variation is that at least one of said outer or inner surfaces is rounded.

The cylindrical inner surface may have a diameter D _and less than the diameter D _{in the} exit bore.

A major advantage of the output electrode node arranged in accordance with the present invention is the ability to separate the hottest central portion of the plasma from the colder edge gas layer. This is evident in discharge chambers with an axial flow of working gas by allowing the temperature of the discharge plasma to rise.

Separation of the colder edge layer of the effluent gas is even more pronounced in discharge chambers with tangential gas inlet, where in addition it substantially or completely limits the tangential component of velocity in the effluent stream, thus achieving a higher temperature of the plasma stream. Furthermore, a direct discharge of plasma from the discharge chamber is achieved and, in addition, the hydrodynamic and temperature characteristics of the plasma stream can be controlled by varying the amount of cold gas to be discharged. If it is necessary to protect the escaping plasma with a shielding gas, the design of the outlet electrode node allows the shielding gas to be rectified to cover the protruding plasma and the plasma-treated material.

The construction of the output electrode node constructed in accordance with the present invention is illustrated in the accompanying three drawings, in which Fig. 1 is a longitudinal section through a discharge chamber with a tangential p-lyn input and Figs. 2-6 illustrate various rectifier segment shape variations and different colder layer rectifier options. gas.

In the exemplary embodiment, a discharge chamber 1 is provided with a tangential gas supply 2 located near the cathode 3, which is at one end of the discharge chamber

1. At the other end is a newly formed output electrode node. An arc is burning between the two electrodes. This node is formed by a funnel-shaped widening outlet 12 into which the rectifier segment 5 fits. The inner surface of the outlet opening 12 may be either flat or curved. Its shape is mostly governed by the requirement where the edge should be directed

The cooler gas layer 11, which fits into the outlet opening, always has a ring shape whose inner surface is in the form of a cylinder, through which the hottest central part of the gas exits separately. The outer surface 7 of the rectifier segment S is conically tapering towards the interior of the discharge chamber 1, but does not touch the inner surface of the outlet opening 12 so that the peripheral cooler gas layer 11 flows through the slit 10. Said outer surface 7 may be flat as shown in FIG. 1, 2, 4. The shape of the outer surface 7 is chosen to separate at the right place the hottest central portion of the gas from the edge of the cooler gas layer 11. to mix the exiting plasma and cool the peripheral cooler layer of gas 11.

Another function of the outer surface 7 is to direct the outflow of the edge cooler gas layer 11 according to the technological requirements. This possibility becomes particularly important if the discharge chamber 1 is injected along its wall with a shielding gas, which can be very expensive. Referring to FIG. 1, the frigid cooler layer of gas 11 or shielding gas can be removed in a wider cone around the flowing plasma. This protects the plasma against the surrounding atmosphere and at the same time the shape of the plasma can be influenced. The outer surface shaped according to FIG. 2 allows the shielding gas to be rectified in a narrow cone adjacent to the plasma stream. If it would not be desirable for a peripheral, cooler gas layer 11 or shielding gas to flow around the free plasma stream, they may be discharged from the discharge chamber at different angles or may be used in recirculation, either because it is preheated gas or expensive protective gas.

Another functional element of the deflection segment 5 is the inner diameter D _{and the} ring, which may either be smaller than the diameter D _{in k of the} discharge chamber 1 in front of the outlet opening 12, or it may be equally large or possibly larger.

In addition to the rectifier function, the rectifier segment 5 can also assume the function of the output electrode. In this case, it is marked with a © in all figures. This combination of functions is particularly advantageous, since this eliminates the need to place a separate output electrode either upstream or downstream of the rectifying segment 5. Another combination option is shown in Figure 5, wherein at least a portion of the rectifying segment 3 forms the output electrode. By isolation 13, the output electrode is insulated and the remaining lower part only functions as rectifiers. Depending on the size of the slot 10, the outer surface 7 can also be electrically insulated, which is shown in FIGS.

The rectifier segment 5 is mounted on a shifting device, for example, on a cooled bracket 8 that slides on the guide

9. The displacement device allows the deflection segment 5 to move in the direction of the longitudinal axis of the discharge chamber 1, thereby varying the size of the slot 10 between the outer surface 7 of the deflecting segment 5 and the discharge opening 12 of the discharge chamber 1. this also affects the temperature of the emerging plasma and possibly the shape of the plasma tip.

Claims (6)

SUBJECT Plasma discharge discharge electrode node comprising a discharge chamber discharge opening and an output electrode, characterized in that an annular deflection segment (5) with a cylindrical inner surface (6) for displacing a central outlet is displaceably disposed in the funnel-extending discharge opening (12). a portion of the gas and with a conical outer surface (7), the apex of which is directed into the discharge chamber (11), with a slot (10) between the outer surface (7) and the inner surface of the outlet opening (12) and the deflection segment (5) is controlled by a displacement device for movement in the direction of the longitudinal axis of the discharge chamber (1). 2. A plasma electron discharge chamber node according to claim 1, wherein at least a portion of the rectifying segment (5) is simultaneously an output electrode. vynalezu 3. A plasma electron discharge chamber node according to claim 1, characterized in that the outer surface (7j) of the rectifying segment (5) and the inner surface of the outlet opening (12) are flat. 4. The plasma electrode discharge electrode node according to claim 1, wherein at least one of said outer or inner surfaces is rounded. 5. A plasma electron discharge chamber node according to claim 1, characterized in that the cylindrical inner surface (6) has a diameter (D _a ) equal to the diameter (D _vk ) of the outlet opening (12). 6. A plasma electron discharge chamber node according to claim 1, wherein the cylindrical inner surface (6) has a diameter (D _and j smaller than the diameter (D _vIt ) of the outlet orifice (12).