EP0446337A1

EP0446337A1 - Plasma generator with hollow cathode for the treatment of powders by means of plasma

Info

Publication number: EP0446337A1
Application number: EP19900915317
Authority: EP
Inventors: Michel Vardelle; Istvan Saray; Pierre Léon Jacques FAUCHAIS
Original assignee: Centre National de la Recherche Scientifique CNRS
Current assignee: Centre National de la Recherche Scientifique CNRS
Priority date: 1989-10-05
Filing date: 1990-10-04
Publication date: 1991-09-18
Also published as: FR2652981A1; WO1991005449A1

Abstract

Ce générateur comprend une anode (4), une cathode creuse (6) dont une première extrémité (16) est disposée en regard de l'anode, des moyens (28) d'injection dans la cathode creuse, par la deuxième extrémité de celle-ci, d'une poudre à traiter qui est mise en suspension dans un gaz porteur, et des moyens (14) de répartition annulaire uniforme du plasma autour de la première extrémité de la cathode, au niveau de cette première extrémité. Application au traitement de surfaces et à la métallurgie extractive.This generator comprises an anode (4), a hollow cathode (6), a first end (16) of which is disposed opposite the anode, means (28) for injecting into the hollow cathode, through the second end of that here, a powder to be treated which is suspended in a carrier gas, and means (14) for uniform annular distribution of the plasma around the first end of the cathode, at this first end. Application to surface treatment and extractive metallurgy.

Description

HOLLOW CATHODE PLASMA GENERATOR FOR PLASMA POWDER TREATMENT.

DESCRIPTION

The present invention relates to a hollow cathode plasma generator for the treatment of powders by plasma. It applies in particular to surface treatment as well as to extractive metallurgy.

Document FR-A-2 514 223 which is hereinafter called document I and to which reference will be made, is already known as a hollow cathode plasma generator.

This generator has the drawback of not having a satisfactory weight yield. "Weight yield" means the ratio of the weight of the powder which is actually collected on the target in projection or treated in the plasma arc in extractive metallurgy, to the weight of the powder which is injected into the hollow cathode of this generator.

The object of the present invention is to remedy this drawback by proposing a plasma generator with a hollow cathode whose weight yield is better, which allows it to process more powder than the known generator mentioned above.

Specifically, the subject of the present invention is a plasma generator intended for the treatment of a powder by plasma, this generator comprising:

- an anode,

a hollow cathode, a first end of which is disposed opposite the anode, and

means of injection into the hollow cathode, by the second end of the latter, of the powder in suspension in a carrier gas, this generator being characterized in that it further comprises means for uniform annular distribution of the plasma around the first end of the cathode, at this first end.

When the generator which is the subject of the invention operates, the means of uniform annular distribution make it possible to obtain, at the first end of the hollow cathode, a plasma ring such as this first end (which, seen from the front, also has a crown shape) and this plasma crown are concentric.

In the absence of these means of uniform annular distribution, the plasma crown tends to excent rat ion, resulting in a "loss" of powder entrained in the cold areas of the plasma jet.

With the means of uniform annular distribution, there is no excess rat i on and the weight yield is therefore improved.

It should be noted that if, at the level of the first end of the hollow cathode, the plasma does not have the shape of a crown (closed) but for example of a half-moon, or more generally of a " crown "having an opening, the powder particles leak through this opening, resulting in a loss of yield.

To obtain a (closed) plasma crown at the first end of the hollow cathode, the hollow cathode should have an inside diameter at this first end (diameter of the hole in the first end) sufficiently small for a given value of the cathodic current, or arc current, and for a given powder flow rate, while having a fairly small external diameter (and therefore a fairly thin wall) to allow heating of the first end leading to a suitable thermoelectronic emission.

As a purely indicative and in no way limitative, for a cathode current intensity greater than 250 A and for a flow rate of the order of 800 g of powder per hour, the internal diameter can be of the order of 1 mm and the external diameter of around 2 mm; for a cathode current intensity greater than 250 A and a powder flow rate of the order of 1.5 kg / h, the internal diameter can be of the order of 1.5 mm and the external diameter of the order of 2.5 mm. Of course, the inside diameter and the outside diameter can be increased if the cat odic current is increased.

To obtain a uniform annular distribution of the plasma, it is possible to use means for uniformly cooling the plasma around the first end of the cathode, at this first end.

Such cooling of the plasma prevents the concentration of the latter on a point on the cathode and makes it possible to obtain the uniform annular distribution desired.

According to a particular embodiment of the generator which is the subject of the invention, the cooling means comprise, between the cathode and the anode, an annular piece which conducts electricity and heat, electrically isolated from the rest of the generator and provided with means for circulating a refrigerant, and the first end of the cathode is placed on the axis of the part, in the vicinity of the latter.

The annular part may comprise a convergent-divergent, the first end of the cathode being placed at the junction of the converge and divergent.

According to a preferred embodiment of the generator object of the invention, in order to avoid the deposition of particles of molten powder inside the cathode, at the level of the first end thereof, this generator further comprises means for accelerating the powder particles, particles which are located near the internal face of the hollow cathode, in the vicinity of the first end thereof.

These means of acceleration can include:

- A central tube which is placed in the hollow cathode along the axis thereof, one end of which is located in the cathode. hollow near the first end thereof and the other end of which is connected to the means for injecting the powder suspended in the carrier gas, and

- Means for injecting a gas into the second end of the hollow cathode, between the internal face of the latter and the external face of the central tube.

Then, preferably, the pressure of the carrier gas is at least equal to about 8.10 Pa.

In a preferred embodiment of the invention, the cathode being extended by a nozzle in the direction of the anode, the generator further comprises, between the means for uniform annular distribution of the plasma and the anode, a vortex zone comprising at least a vortex chamber into which the gas used to generate the plasma is injected and the diameter of each vortex chamber is at least equal to approximately four times the diameter of the nozzle.

This prevents the powder from sticking to the walls of the generator nozzle.

Each vortex chamber can be delimited by a peripheral wall pierced with channels opening into the chamber tangent to the internal face of this wall.

The anode of the generator which is the subject of the present invention can be produced in various ways, depending on the applications envisaged:

In a particular embodiment, the cathode being extended by a nozzle in the direction of the anode, this anode extends the nozzle and has a bore which has a symmetry of revolution around an axis coincident with that of the nozzle and whose diameter is higher than that of the nozzle.

In this way, the powder is prevented from sticking to the anode thus produced.

In another particular embodiment, the generator further comprises means for producing an auxiliary plasma jet, this jet being perpendicular to the axis of the hollow cathode and constituting the anode of the generator.

In this way, the sticking of powder particles on the anode is also avoided.

In another particular embodiment, the generator comprises at least one electrically conductive tube which acts as an anode, the axis of which is perpendicular to the axis of the hollow cathode and which is placed so as to be tangent to the column of plasma that the generator is able to produce, and means for rotating the tube around its axis.

In this way, the bonding of powder particles on the anode is further avoided.

Finally, in a particular application of the invention to extractive metallurgy, the generator may comprise, facing the cathode, an electrode intended to be brought to an electrical potential greater than that to which the cathode, the treatment of the powder, even of the oxide type, by the generator leading to an electrically conductive material which forms on the electrode, the anode being constituted by this material formed on the electrode.

The present invention will be better understood on reading the following description of exemplary embodiments given for purely indicative and in no way limitative, with reference to the appended drawings in which: FIG. 1 is a schematic longitudinal sectional view of a mode of particular embodiment of the generator object of the invention,

- Figure 2 is section II-II of the figure

1,

FIG. 3 is a schematic view of the end of the hollow cathode that the generator represented in FIG. 1 comprises,

FIG. 4 is a schematic cross-sectional view of a vortex gas diffuser or chamber that the generator shown in FIG. 1 comprises,

FIG. 5 illustrates schematically and partially a generator according to the invention, which comprises two vortex chambers instead of one,

FIG. 6 is a schematic view of a generator according to the invention in which the anode is produced by means of a plasma jet,

FIG. 7 is a schematic view of another generator in accordance with the invention, in which the anode is produced by means of a rotating and electrically conductive tube, and

- Figure 8 schematically illustrates another generator according to the invention, in which the anode consists of the material resulting from the treatment of a powder by this generator.

The particular embodiment of the generator object of the invention, which is shown schematically in longitudinal section in Figure 1, has generally a symmetry of revolution about an axis X and comprises a metal body 2, an anode 4 and a cathode hollow 6.

The anode 4 has the same potential as the body 2 and is at one end of this body. The anode 4 has a bore 8 along the X axis.

The hollow cathode 6 is a tube of axis X which is placed in the body 2. This tube is inserted in a metal cathode holder 10 and the end of this tube, which is on the side of the anode 4, protrudes of the cathode holder 10 and has a conical shape converging towards the anode. The cathode holder 10 is inserted into an electrically insulating sheath 12, for example made of a plastic material such as that which is marketed under the name DELRIN.

The sheath 12 is itself inserted into the body 2.

To treat a powder by means of the generator shown in FIG. 1, it is mixed with a carrier gas, for example argon, and this mixture is injected into the hollow cathode by the other end of it. this.

This hollow cathode 6 is made of a material, for example thoriated tungsten, which is capable of emitting electrons when it is heated ⁽ thermionic emission), these electrons contributing, in a known manner, to the formation of plasma ( generated by a gas such as argon. When the anode is brought to an appropriate potential, higher than the potential to which the cathode is brought).

The generator schematically represented on Figure 1 further comprises, between the anode and the end of the cathode which is opposite this anode, an annular part 14 intended to cool the plasma in the vicinity of this end of the cathode. This part, which has a symmetry of revolution around the X axis, is metallic and therefore electrically and thermally conductive. In addition, it is electrically isolated from the rest of the generator shown in Figure 1 and it is left at a floating potential. IT is cooled by circulation of a coolant such as water.

This part 14 forms a convergent-divergent, the end 16 of the cathode, which is opposite the anode, being located at the junction between the convergent and the divergent.

The distance e (FIG. 3) between this end and this junction is small, less than or equal to 1 mm.

It should be emphasized that no gas is injected into the chamber located between room 14 and the cathode so as not to cool the end of the cathode and to avoid a temporary snag.

It is advisable to avoid the sticking of the powder on the internal face of the end 16 of the cathode. Such bonding takes place with the powder particles whose speed is almost zero. Indeed. The powder particles which deposit are those which do not have enough impulse to enter the plasma and which tend either to deposit on the internal face of this one, or to remain in the End 16 of the cathode hollow where they are melted and remain glued.

According to POISEUILLE's law, these particles come from the peripheral zone of the interior of the hollow cathode, zone in which the speed of the gas carrier is almost zero, and the quantity of particles whose speed is almost zero is inversely proportional to the inside diameter of the hollow cathode. This quantity is therefore all the more important as this internal diameter is small.

In order to remove these slow particles, they are re-accelerated by means of a gas flow which is circulated in the vicinity of the internal face of the hollow cathode.

To this end, a central tube 18 of axis X (FIG. 3) is placed in the hollow cathode 6. One end of this central tube 18 protrudes from the other end 20 of the hollow cathode (FIG. 1 ⁾ while L ' another end of the tube 18 is located in the hollow cathode 6, at the end 16 thereof. The outside diameter of the tube 18 is such that there is a space between this tube 18 and the internal face of the hollow cathode all along this hollow cathode.

We see in Figure 3 that the inner diameter of the hollow cathode is smaller at the end 16 thereof than in the rest of the hollow cathode. At this end 16, there is thus a small space between the tube 18 and the internal face of the hollow cathode. The tube 18 is held in place by means of a centering piece in the form of a ring 22 which the tube 18 passes through and which is inserted into the hollow cathode 6, for example in the vicinity of the end 16 of the latter. Of course, this ring 22 is pierced along the axis X to allow the passage of the re-acceleration gas.

We see in Figure 1 that the end 20 of the hollow cathode opens into a chamber 24 formed in the cat-ode holder 10. A conduit 26 communicates on one side with this chamber 24 and the other with means d supply of re-acceleration gas, this gas being for example argon.

The central tube 18 extends beyond the end 20 of the hollow cathode and is connected to one end of another tube 28 by means of suitable connection means 30.

The other end of this tube 28 is connected to means 32 allowing the mixture of powder and carrier gas to be obtained. Thus, this mixture is injected into the plasma via the central tube 18 while a current of Lérat ion reacess gas circulates in the hollow cathode, around the tube 18.

In certain applications of the generator shown in FIG. 1, a hollow cathode is used whose maximum outside diameter does not exceed 4 mm in order to limit the electrical power consumed. This implies the use of a central tube 18 whose outer diameter is less than 1 mm, for example of the order of 0.6 to 0.8 mm and therefore the use of means 32, called "powder distributor ", in which the pressure of the carrier gas is greater than 8.10 Pa, in order to increase the flow rate of powder transported (with a flow rate of carrier gas so as not to disturb the plasma too much, by limiting the length of the cold zone in the center The plasma column created from the hollow cathode where the plasma arc "bursts" in a ring) and the momentum of the powder particles (to limit the bonding phenomena).

To this end, a powder dispenser is used which is of the type shown in FIG. 9 of document I or of the type found in commerce, but suitably reinforced.

5 to withstand a pressure greater than 8.10 Pa.

The plasma generator schematically represented in FIG. 1 also comprises, between the part 14 and the anode 4, a vortex chamber 34 and, between this vortex chamber 34 and the anode 4, a plurality of annular segments 36 electrically conductive, for example made of copper , which are electrically isolated from each other as well as from the rest of the generator and Left at a floating electrical potential.

The axis of the vortex chamber 34 and of the annular segments 36 is the X axis. The internal diameter of the annular segments 36 is equal to the diameter of the end of the divergent part 14, the divergent which is turned towards the segments 36 .

This diverging point and the channel delimited by the annular segments 36 form the nozzle of the generator of FIG. 1, this nozzle extending by the drilling of the anode 4.

The vortex chamber 34 is delimited, on one side, by the part 14 and on the other side, by one of the annular segments, which bears the reference 36a in FIG. 1. The other annular segments 36 all have the same outside diameter. The role of these annular segments is to lengthen the nozzle while avoiding parasitic arc-nozzle short-circuits. This implies that their length L is such that

The

Edx <V +

/ VS

where E is the electric field in the segment (function of its diameter, the nature of the plasma gas and the efficiency of the vortex ⁾ and V and V are

AC respectively Anode and cathode voltage drops. A simple rule that can be applied is that in general Kd, d being the diameter of the segment. The segment 36a has an outside diameter greater than that of the other segments 36.

The vortex chamber 34 is further delimited at its periphery by an electrically insulating annular ring 38, which is provided with bores allowing the arrival, in the vortex chamber 34, of a gas such as argon, intended to generate Plasma.

An annular chamber 40 is provided between the annular ring 38 and the body 2 of the generator. The gas intended to generate the plasma arrives in this chamber 40 by means of suitable conduits, provided in the body 2 of the generator. From the annular chamber 38, this gas passes into the vortex chamber 34, thanks to the bores which are provided in the annular ring 38. These bores are designed so as to obtain a turbulent flow of gas in the chamber 34.

The internal diameter of the vortex chamber is at least four times greater than the internal diameter of the annular segments 36 and 36a. It can be seen in FIG. 4 that the holes in the annular ring 38 consist of oblique channels 42 which come tangentially to the internal face of the annular ring 38. Preferably, at least a dozen such channels 42 are used. The diameter of each of these channels is chosen so that the speed of the argon injected through these channels is at least of the order of 200 m per second.

By thus injecting the plasma generating gas in a peat L Lonnai manner beyond the cooling part 14, the sticking of powder particles on the walls of the generator nozzle is avoided, bonding which would occur, in the absence vortex chamber, because the jet of powder injected into the plasma along the X axis tends to diverge, particles of powder thus escaping from the plasma column and coming to stick on the walls of the nozzle. Indeed. The particles remain confined first by (then in) the plasma column which, in the vicinity of the cathode, is a hollow cylinder and which gradually closes. The viscosity of the plasma cylinder and its high momentum prevent particles from diverging, causing them to gradually penetrate the plasma column when it closes further down the nozzle. However, to avoid this plasma column coming too quickly in the vicinity of the wall where the particles could stick. The vortex is then necessary to cause better constriction of the plasma column in the center of the nozzle.

The use of the vortex chamber makes it possible to increase the quantity of cold gas in the vicinity of the wall of the nozzle and to obtain good constriction of the plasma column.

It can be seen in FIG. 1 that the diameter of the bore 8 of the anode 4 is greater than the internal diameter of the annular segments 36 and 36a and is for example of the order of 1.2 to 1.5 times this internal diameter of the segments annulars 36 and 36a. Powder particles which are strongly accelerated in the plasma are thus avoided from coming to be fixed on the internal face of the anode.

The annular segments 36 and 36a are isolated from each other and from the anode 4 by means of thin rings of mica 44 (FIG. 3) whose internal diameter is at least equal to the internal diameter of the segments 36 and 36a. In addition, the periphery of the segment 36a is opposite a shoulder ent circular interior of the body 2 and this segment 36a is electrically isolated from this shoulder by means of an electrically ring insulator which is located at the periphery of segment 36a and which is not shown in FIG. 1.

In this figure 1, it can be seen that the anode 4, the body 2, the annular segments 36 and 36a, the cooling part 14 and the cathode 6 as well as the cathode holder 10 are cooled by circulation of a refrigerant fluid such than water. For this purpose, the body 2 is provided with a conduit 46 allowing the arrival of water and a conduit 48 allowing the outlet of the water, the entire generator being provided with various chambers and various conduits. interiors allowing the cooling in question.

Of course, seals 50 are placed in the appropriate places to prevent water from entering the various spaces where the various gases used in the generator shown in FIG. 1 circulate.

In particular, at the annular segments 36 and 36a, the water tightness is obtained by means of two O-rings 52, one of these being between the anode and the adjacent segment 36, and L ' other, between segment 36a and adjacent segment 36. In addition, the thin mica crowns 44 are glued to the annular segments and the glue, which overflows at the periphery of these thin crowns 44, makes it possible to obtain the necessary seal between the segments 36.

It will be noted that the various annular segments allow the elongation of the plasma column.

Instead of using a single vortex chamber, it is possible to use at least two as shown in FIG. 5. These vortex chambers are adjacent and separated from each other by an annular segment 36b of the type of segment 36a of Figure 1, while the vortex chamber which is closest of the anode is separated from the other annular segments 36 by an annular segment 36c also of the type of segment 36a in FIG. 1.

The use of two successive vortex chambers, supplied by the plasma generating gas, allows the nozzle to be lengthened and therefore the plasma arc voltage to be increased. In fact, due to the high viscosity of the plasma and the fairly rapid heating of the gas surrounding the column, the vortex is fairly quickly absorbed and, for a long nozzle, it is preferable to create a second one further downstream in order to cool. again the periphery of the column and again cause the constriction of the latter. However, it is possible to inject the plasma-generating gas into the vortex chamber which bears the reference 54 in FIG. 5 and which is closest to the part 14 and to inject into the second vortex chamber, which bears the reference 56 in the FIG. 5, another gas (possibly mixed with the plasma generating gas), according to the applications envisaged for the generator of FIG. 1.

For example, for nitriding, nitrogen could be injected into the vortex chamber 56.

In other applications, hydrogen may be used. Hydrogen significantly increases the heat transfer between the plasma and the powder particles and increases the constriction of the plasma column in the nozzle.

The use of oxygen as another gas injected into the vortex chamber 56 also makes it possible to increase the constriction of the plasma column in the nozzle (hence an increase in the temperature of the plasma column and therefore increased heat transfer from plasma to powder particles). In addition, oxygen avoids the reduction of certain oxides, such as for example SiO, reduction which gives rise to other compounds whose very high vapor pressure harms the heating of the powder particles.

FIGS. 6 to 8 show diagrammatically other generators in accordance with the invention in which the metallic annular part 4 which played the role of anode in the generator of FIG. 1 no longer plays this role of anode, but is still at the same potential as the body 2 of the generator.

In the generator 57 schematically represented in FIG. 6, the anode is constituted by an auxiliary plasma jet 58 which is perpendicular to the axis X and sent to the plasma column 60 produced by the generator 57. The plasma jet 58 is opposite part 4 and at a distance from it which can be of the order of 40 to 50 mm. The auxiliary jet 58 is produced by an auxiliary plasma generator 62, with a relatively low electrical power, of the order of a few kW. This jet 58 thus comes to lick the plasma column 60.

For the operation of the generator 57, two current generators 64 and 66 are used. The + terminals of these generators 64 and 66 are connected to each other and grounded. The + terminal of the generator 64 is also connected, via a switch 68, to the anode of the auxiliary generator 62. A high frequency source 70 is also used, one terminal of which is earthed. and the other terminal of which is connected to the cathode of the generator 57 as well as to the terminal - of the current generator 66 by means of a switch 72. The terminal - of the current generator 64 is connected to the cathode of the auxiliary generator 62. The generator body plasma 57 is grounded through a switch 74 and an electrical resistor - bias 76. An inductor 78 is provided between the terminal - of the current generator 64 and the cathode of the plasma generator 62 to avoid the return of the high frequency and, for the same reason, an inductor 80 is provided between the terminal - of the current generator 66 and the terminal of the high frequency source 70, which is connected to the cathode of the generator plasma 57.

With such an electrical assembly, the + terminal of the current generator 64 is in a way transferred to the end of the plasma jet 58 which therefore plays the role of anode for the generator 57.

This also prevents any sticking of powder particles on this anode.

In Figure 7, there is shown schematically a generator 57a according to the invention whose anode is no longer constituted by the part 4, which is here at a floating potential, but by a rotating electrically conductive tube 82, which is cooled by internal circulation of water and whose axis is perpendicular to the X axis. This tube is located outside the generator 57a, opposite part 4, and placed in such a way that it is tangent to The plasma column 60 generated.

The tube 82, for example made of copper, is brought to a positive potential with respect to the cathode of the generator 57a.

The tube 82 is rotated at constant speed by means of a pulley 84 which is fixed to one end of the tube and has the same axis as the latter.

This pulley is rotated by another pulley 86, by means of a belt 88.

The other pulley 86 is itself driven in rotation at constant speed by means of a motor not shown. For purely indicative and in no way limitative, the rotation speed of the tube is of the order of 1500 to 2000 revolutions / minute.

In FIG. 7, a deposit of material 90 is also seen on a target 92, this material resulting from the treatment of the powder by the plasma produced by the generator 57a.

Instead of a single rotating tube 82, two could be used, the axes of which are parallel and always perpendicular to the axis X, these two tubes being tangent to the plasma column 60 and situated on the same side of that -this.

The plasma generator 57b according to the invention, which is schematically represented in FIG. 8, is applied to extractive metallurgy. To this end, a crucible, for example made of ceramic, is used, at the bottom of which is placed an electrode 94 called "sole electrode". As the powder is treated by the generator 57b, the crucible fills with a material 96 which remains in the liquid state due to the heat given off by the plasma. It is for example an oxide, which, in the liquid state, is in ionic form and therefore electrically conductive. It is the material contained in the crucible which plays the role of anode for the generator 57b shown in FIG. 8. In fact, at the beginning, it is the electrode 94 which plays this role of anode.

To operate the generator 57b, a current generator 98 is used whose terminal - is connected to the cathode of the generator 57b and whose terminal + is connected to the electrode 94.

The part 4 is here at a floating potential.

In another application of the invention. The material formed 96 could be in the solid state and would still play the role of an anode. For proper operation of the generator 57b, it is preferable that the axis of the plasma column 60 ⁽ which coincides with the axis X) be perpendicular to the surface of the material formed in the crucible 93 or make, with this surface, a large angle, greater than 60 °.

Starting, in the configuration of Figure 8, is ensured by first lighting the arc on part 4 (Figure 1) to create a conductive column, then bringing the sole electrode to the potential of this part 4 and then putting it at a floating potential.

Claims

1. Plasma generator intended for the treatment of a powder by plasma, this generator comprising:

- an anode (4, 58, 82, 96),

a hollow cathode (6), a first end (16) of which is disposed opposite the anode, and

- Means (28) for injecting into the hollow cathode, by the second end thereof, powder suspended in a carrier gas, this generator being characterized in that it further comprises means (14) uniform annular distribution of the plasma around the first end of the cathode, at this first end.

2. Generator according to claim 1, characterized in that the distribution means comprise means (14) for uniform cooling of the plasma around the first end of the cathode, at this first end.

3. Generator according to claim 2, characterized in that the cooling means comprise, between the cathode (6) and the anode (4, 58, 82, 96), an annular piece (14) conductive of electricity and heat, electrically isolated from the rest of the generator and provided with means for circulating a refrigerant fluid, and in that the first end (16) of the cathode is placed on the axis (X) of the part, in the vicinity of the latter.

4. Generator according to claim 3, characterized in that the annular part comprises a convergent-d vergent and in that the first end (16) of the cathode (6) is placed at the junction of the convergent and the diverging.

5. Generator according to any one of claims 1 to 4, characterized in that it comprises further means (18, 26) for accelerating the powder particles, particles which are located near the internal face of the hollow cathode (6), in the vicinity of the first end (16) thereof.

6. Generator according to claim 5, characterized in that the acceleration means comprise:

- a central tube (18) which is placed in the hollow cathode (6) along the axis (X) thereof, one end of which is located in the hollow cathode near the first end (16) of the latter ci and the other end of which is connected to the means (28) for injecting the powder suspended in the carrier gas, and

- Means (26) for injecting a gas at the second end of the hollow cathode, between the internal face of the latter and the external face of the central tube (18).

7. Generator according to claim 6, characterized in that the pressure of the carrier gas is at ^•• > less equal to about 8.10 Pa.

8. Generator according to any one of claims 1 to 7, characterized in that, the cathode (6) being extended by a nozzle in the direction of the anode. The generator further comprises, between the means (14) for uniform annular distribution of the plasma and the anode (4, 58, 82, 96), a vortex zone comprising at least one vortex chamber (34, 54-56) into which is injected the gas used to generate the plasma and in that the diameter of each vortex chamber is at least equal to about four times the diameter of the nozzle.

9. Generator according to claim 8, characterized in that each vortex chamber (34, 54-56) is delimited by a peripheral wall (38) pierced with channels (42) opening into the chamber tangent ie L ely to the internal face of this wall.

10. Generator according to claim 8, characterized in that the nozzle comprises, between the anode and the vortex zone, a succession of electrically conductive coaxial rings (36, 36a) which are electrically isolated from each other and from the rest of the generator, and whose axis is The axis of the cathode.

11. Generator according to any one of claims 1 to 10, characterized in that, the cathode (6) being extended by a nozzle in the direction of the anode, this anode extends the nozzle and comprises a bore (8) which has a symmetry of revolution around an axis (X) coincident with that of the nozzle and whose diameter is greater than that of the nozzle.

12. Generator according to any one of claims 1 to 10, characterized in that it further comprises means (62) for producing an auxiliary plasma jet (58), this jet being perpendicular to the axis (X) of the hollow cathode (6) and constituting the generator anode.

13. Generator according to any one of claims 1 to 10, characterized in that it comprises at least one electrically conductive tube (82) which acts as an anode, the axis of which is perpendicular to the axis (X ) of the hollow cathode (6) and which is placed so as to be tangent to the plasma column (60) that the generator is capable of producing, and means (84, 86, 88) for rotating the tube ( 82) around its axis.

14. Generator according to any one of claims 1 to 10, characterized in that it comprises, facing the cathode, an electrode (94) intended to be brought to an electrical potential greater than that to which the cathode is carried (6), The treatment of the powder by the generator leading to an electrically conductive material (96) which forms on the electrode, and in that the anode is constituted by this material formed on the electrode.