EP0817547A1 - Plasma torch head - Google Patents

Abstract

The invention relates to a plasma torch head comprising an axial electrode (10) and a peripheral nozzle (12) in the form of a cup, the bottom (22) of which comprises an axial duct (24) for ejecting the plasma jet and of which the side wall surrounds the electrode. The electrode (10) and the nozzle (12) are axially displaceable relative to each other with a view to bringing them into temporary contact along a contact surface to initiate an electric arc between the electrode (10) and the nozzle (12). Application to plasma cutting torches. <IMAGE>

Description

The present invention relates to a torch head with plasma, of the type comprising an axial electrode and a cup-shaped peripheral nozzle with bottom has an axial pipe for ejecting the plasma jet and whose side wall surrounds the electrode, the electrode and the nozzle being axially displaceable one by relation to the other with a view to putting them in contact temporary following a contact surface to initiate a electric arc, called pilot arc, between the electrode and the nozzle.

Such torch heads are used in plasma torches for welding, cutting, heat treatment or thermal spraying.

In steady state, an electric arc is established at through the axial ejection duct between the electrode and the metal piece worked. The electrode and this part are connected to the terminals of an electric generator.

In order to initiate the electric arc, it is known to temporarily contact the end surface of the electrode and the bottom surface of the nozzle.

In a first type of installation, the nozzle and the electrode are temporarily connected to the terminals of a electric generator, so that a pilot arc takes birth directly between these two elements. The arc pilot is then transferred to the workpiece under the effect of the plasma flow. After the transfer of the arc, the nozzle is no longer supplied by the generator, the power being applied to the workpiece.

In a second type of installation, the nozzle is not not powered. The pilot arc is initiated by support of the conductive nozzle on the workpiece and contact of the electrode with the nozzle. A short-circuit is then established between the workpiece and the electrode through the nozzle, so that an arc arises between the nozzle and the electrode during their spacing.

In known torch heads, the electrode has a flat end surface and the nozzle also has a flat bottom. Thus, bringing the electrode into contact with the nozzle is carried out along most of the surface flat end of the electrode.

The document FR-A-2,650,470 describes, for example, a electrode whose planar end face has a axial counterbore ensuring withdrawal of an insert emissive centrally positioned. This configuration particular solution to the problems related to the deformation of the surface of the insert during the operation. A large flat annular surface dimension remains at the end of the electrode around the counterbore. Contact with the flat bottom of the nozzle takes place over the entire extent of this surface annular.

In known torch heads, contacting of the electrode and the nozzle leads to an interruption momentary flow of plasma gas. So the bow is born in a very poor environment plasma gas. Consequently, the arc is established in a metallic plasma fed by metallic vapors from erosion of the nozzle walls and the electrode.

During the transitional period necessary for the gas stream stabilization, after establishment of the normal operating interval between the electrode and the nozzle, the arc is very unstable and moves from erratically over the entire flat surface of the bottom of the nozzle and in particular near the entrance to the axial ejection duct. This same phenomenon of random displacement of the root of the arc is also found on the surface of the electrode located opposite.

Arc movement causes erosion electric, local mergers and displacements of melting residue on the outer walls of the electrode and the internal walls of the nozzle. These phenomena quickly lead to a change in the condition of surfaces channeling the plasma gas. In particular, under the effect of the plasma gas flow, the residues of fusion converge towards the entry of the ejection duct, modifying its geometry. Geometric modifications surfaces cause disturbances in the flow of the plasma jet, thereby reducing the quality of the work done.

In addition, the alteration of surfaces causes difficulties in obtaining the electric arc during subsequent lighting of the torch, due to increased contact resistance between the electrode and the nozzle.

The object of the invention is to remedy the drawbacks mentioned above and in particular to propose a plasma torch head undergoing little degradation of its internal surfaces during the ignition phase and of which the lifespan is extended, with conservation of working qualities.

To this end, the invention relates to a head of plasma torch comprising an axial electrode and a cup-shaped peripheral nozzle with bottom has an axial duct for ejecting the plasma jet and whose side wall surrounds the electrode, the electrode and the nozzle being axially displaceable one by relation to the other with a view to putting them in contact temporary following a contact surface to initiate a electric arc between the electrode and the nozzle, characterized in that the bottom of the nozzle has a first axial peripheral projection.

• la surface de contact entre le fond de la tuyère et l'électrode est nettement écartée de l'entrée du conduit axial d'éjection de la tuyère. On considère que la ligne de contact est nettement écartée de l'entrée du conduit si celle-ci est située à une distance de l'axe de la tuyère supérieure à au moins quatre fois le rayon minimum du conduit d'éjection et, de préférence, d'environ cinq fois le rayon minimum;
• une face d'extrémité de l'électrode comporte une seconde saillie périphérique axiale, de préférence bombée, dont la crête définit la surface de contact;
• la surface de contact est au moins et de préférence une ligne de contact, continue ou discontinue;
• la face d'extrémité de l'électrode comporte une cuvette axiale délimitée par une surface qui est reliée tangentiellement à la seconde saillie périphérique bordant ladite cuvette axiale;
• le conduit axial d'éjection débouche au sommet de la première saillie portée par le fond de la tuyère, la ligne de contact s'établissant sensiblement à la base de la première saillie;
• le profil de la première saillie correspond sensiblement au profil de la cuvette axiale;
• les surfaces de la cuvette axiale et de la première saillie sont sensiblement tronconiques et la pente de la surface de la cuvette axiale prise par rapport à un plan transversal de la torche est supérieure à la pente de la surface de la première saillie prise par rapport audit plan transversal;
• les surfaces tronconiques sont reliées à leur périphérie extérieure tangentiellement aux surfaces adjacentes les prolongeant;
• le fond de la tuyère a la forme d'un manchon centré sur l'axe de la torche et dont le diamètre est supérieur au diamètre extérieur de la face d'extrémité de l'électrode, la ligne de contact s'établissant sur la surface interne dudit manchon;
• la surface ou ligne de contact est traversée par des rainures sensiblement radiales; et
• ladite électrode comporte un insert à face plane disposé axialement et affleurant à sa face d'extrémité.

Depending on the case, the plasma torch head may include one or more of the following characteristics:

• the contact surface between the bottom of the nozzle and the electrode is clearly spaced from the inlet of the axial nozzle ejection duct. It is considered that the contact line is clearly spaced from the inlet of the conduit if the latter is located at a distance from the axis of the nozzle greater than at least four times the minimum radius of the ejection conduit and, preferably , about five times the minimum radius;
• an end face of the electrode has a second axial peripheral projection, preferably curved, the crest of which defines the contact surface;
• the contact surface is at least and preferably a contact line, continuous or discontinuous;
• the end face of the electrode comprises an axial cup delimited by a surface which is tangentially connected to the second peripheral projection bordering said axial cup;
• the axial ejection duct opens at the top of the first projection carried by the bottom of the nozzle, the contact line being established substantially at the base of the first projection;
• the profile of the first projection corresponds substantially to the profile of the axial bowl;
• the surfaces of the axial bowl and the first projection are substantially frustoconical and the slope of the surface of the axial bowl taken relative to a transverse plane of the torch is greater than the slope of the surface of the first projection taken relative to said transverse plane;
• the frustoconical surfaces are connected at their outer periphery tangentially to the adjacent surfaces extending them;
• the bottom of the nozzle has the shape of a sleeve centered on the axis of the torch and whose diameter is greater than the outside diameter of the end face of the electrode, the contact line being established on the surface internal of said sleeve;
• the surface or line of contact is crossed by substantially radial grooves; and
• said electrode comprises an insert with a flat face disposed axially and flush with its end face.

• la figure 1 est une vue en coupe longitudinale d'une tête de torche à plasma selon l'art antérieur, lors de la mise en contact de l'électrode et de la tuyère;
• la figure 2 est une vue analogue de la tête de torche de la figure 1, l'électrode étant écartée de la tuyère;
• les figures 3 et 4 sont des vues partielles en coupe longitudinale d'une variante de réalisation d'une tête de torche à plasma selon l'art antérieur dans des positions analogues à celles des figures 1 et 2;
• la figure 5 est un détail à plus grande échelle de la figure 4;
• les figures 6 et 7 sont des vues d'un mode de réalisation d'une tête de torche à plasma selon l'invention;
• la figure 8 est une vue analogue à celle de la figure 5 pour la tête de torche des figures 6 et 7;
• les figures 9 et 10 sont des vues analogues à celles des figures 6 et 7 pour une autre variante de réalisation d'une tête de torche à plasma selon l'invention;
• la figure 11 est une vue en élévation de la face d'extrémité de l'électrode de la tête de torche des figures 9 et 10;
• la figure 12 est une vue analogue à celle de la figure 10, montrant un exemple d'écoulement du gaz plasmagène;
• les figures 13 et 14 sont des vues en élévation de variantes de réalisation de la face d'extrémité de l'électrode, montrant le sens d'écoulement du gaz plasmagène; et
• les figures 15 et 16, d'une part, et les figures 17 et 18, d'autre part, sont des vues en coupe longitudinale de variantes de réalisation de têtes de torche à plasma selon l'invention, l'électrode et la tuyère étant représentées respectivement en contact et écartées.

The invention will be better understood on reading the description which follows, given solely by way of example and made with reference to the drawings in which:

• Figure 1 is a longitudinal sectional view of a plasma torch head according to the prior art, when the electrode and the nozzle are brought into contact;
• Figure 2 is a similar view of the torch head of Figure 1, the electrode being spaced from the nozzle;
• Figures 3 and 4 are partial views in longitudinal section of an alternative embodiment of a plasma torch head according to the prior art in positions similar to those of Figures 1 and 2;
• Figure 5 is an enlarged detail of Figure 4;
• Figures 6 and 7 are views of an embodiment of a plasma torch head according to the invention;
• Figure 8 is a view similar to that of Figure 5 for the torch head of Figures 6 and 7;
• Figures 9 and 10 are views similar to those of Figures 6 and 7 for another alternative embodiment of a plasma torch head according to the invention;
• Figure 11 is an elevational view of the end face of the torch head electrode of Figures 9 and 10;
• Figure 12 is a view similar to that of Figure 10, showing an example of plasma gas flow;
• Figures 13 and 14 are elevational views of alternative embodiments of the end face of the electrode, showing the direction of flow of the plasma gas; and
• Figures 15 and 16, on the one hand, and Figures 17 and 18, on the other hand, are views in longitudinal section of alternative embodiments of plasma torch heads according to the invention, the electrode and the nozzle being shown respectively in contact and separated.

The plasma torch head shown in the Figures 1 and 2 is intended, for example, for cutting metal parts. It has a general form of X-X axis revolution. It mounts on a body of suitable plasma torch, for example by snap-fastening in this body.

This head essentially comprises an electrode 10 of axis X-X and a peripheral nozzle 12, both adapted to be associated with generators of appropriate electrical potential. The electrode and the nozzle are rigidly connected by a cover (not shown) forming a plasma gas diffuser.

The electrode 10 is mounted movable axially by with respect to the nozzle 12 by any appropriate means, between an arc striking position in contact with the nozzle and a working position axially spaced from the nozzle. These positions are shown respectively in Figures 1 and 2.

The electrode 10 is made of a suitable metal and has a general form of revolution. It includes internal conduits 14 intended for the circulation of a coolant. An emissive insert 16 on the face flat, in hafnium for example, is arranged axially at the end of the electrode 10. It is flush with the center of the end face 18 thereof. The electrode has further on its end face 18 a projection convex axial device 20 forming a rim continuous device surrounding a flat surface 18A at center of which the insert is flush 16. The projection peripheral 20 is formed by a toroidal bead coming of material and disposed at the outer periphery of the electrode.

The nozzle 12 has a general shape of an axle cup X-X. It has a flat bottom 22 crossed by a axial duct 24 for ejecting the plasma gas. The bottom 22 is extended by a side wall 26 surrounding the electrode 10 and delimiting therewith a space 28 substantially annular circulation of plasma gas to conduit 24.

In FIG. 1, the electrode 10 is in contact with the nozzle 12 along the crest 20A of the projection periphery 20. The contact surface 23 established between the ridge 20A and the bottom 22 is moved away from the entry of the axial ejection duct, so that the surface 22A surrounding the entrance to this conduit is free of all contact with the electrode.

The conduit entrance is defined as the line of rupture existing between the axial ejection duct and the nozzle bottom. If such a breaking line does not exist not and that the diameter of the conduit varies continuously in its connection area with the bottom, the entrance to the duct is defined as the place where the diameter of the duct is 1.5 times the minimum diameter of the drove.

In Figure 1, a short circuit is established between the electrode and the nozzle along the contact line 23 existing between the crest 20A of the projection and a line circular carried by the flat surface 22.

In FIG. 2, the electrode 10 is in the position of working, away from the nozzle 12. When spacing progressive of nozzle 10 and electrode 12, the arc electric arises between a crown 22B of small width containing the circular contact line and the crest 20A of the projection 20. The crown 22B is symbolized by a thick line in this figure.

Under the effect of plasma gas flowing from the annular space 28, the electric arc is blown to then establish between insert 16 and the part to be work not shown. The nozzle supply is then stopped.

According to the embodiment shown in the figures 3 to 5, the nozzle 12 is identical to that of the mode of previous achievement. The end face 18 of the electrode further comprises an axial cup 30 bordered by the peripheral projection 20. The surface 32 delimiting the bowl 30 is frustoconical and connects tangentially the crest of the peripheral projection 20 to the periphery of the plan insert 16.

The peripheral projection 20 is toroidal with a inner radius noted R. The frustoconical surface 32 is tangentially connects to the torus delimiting the projection 20.

According to a first embodiment of the head of torch according to the invention, shown in Figures 6 to 8, the electrode 10 is analogous to the electrode shown in Figures 3 to 5.

On the other hand, the nozzle 12 has a bottom provided a first axial peripheral projection 40, again called axial bending 40, at the top of which opens the axial ejection duct 24.

The profile of the bending 40 corresponds substantially to the profile of the axial bowl 30 formed on the surface end of the electrode. Thus, the surface 42 of the bending 40 is substantially frustoconical. This surface 42 defines with a plane perpendicular to the X-X axis of the torch an angle a substantially equal to 10 ° (Figure 8). The surface 32 of the axial bowl 30 defines with this same plane perpendicular to the axis X-X an angle β substantially equal to 12 °. So the slope of the surface of the bowl axial taken in relation to the transverse plane of the torch is slightly greater than the slope of the surface of the bending taken in relation to this same plane. In these conditions, a linear contact is established between the electrode 10 and the nozzle 12 along the projection peripheral 20 and the base of the bending 40 of the nozzle. Of plus, any other point of contact between the electrode and the nozzle is excluded, the height of the bending at any point outside the contact surface being less than the depth of the axial bowl at the point corresponding to this one.

In addition, the frustoconical surface 42 is connected tangentially to the inner surface of the wall side of the nozzle.

It is understood, with regard to FIG. 8, that the gas undergoes plasmagenicity between the frustoconical surfaces substantially parallel 32 and 42, rolling ensuring stabilization of the root of the electric arc on insert 16, during steady state operation of the torch.

In addition, the electric arc being established between the points closest to the electrode and the nozzle, the roots of the emerging electric arc are maintained on the crown 22A of the nozzle and on the crest 20A of the projection. So, as long as the electric arc is not blown by the plasma gas, it is kept in a defined area of small area. The level of electrical erosion being linked to the surface swept by the electric arc, circumscribing the arc to an area reduced limits surface degradation. Moreover, the arc being kept away from the entry of the axial duct ejection, any fusion residues produced do not cannot reach this one, thus guaranteeing the geometric preservation of the duct. We can see that with such an arrangement, the lifetime of the torch head at plasma is elongated.

In this embodiment, the electric arc takes birth in a localized area of small extent and distant from the inlet of the axial ejection duct 24, thus preserving the torch head.

In addition, we see with the torch head Figures 6 to 8 that the inlet wall of the axial duct less ejection from the nozzle thermally than in the embodiments previous.

In other words, having a first projection 40 or bending on the bottom of the nozzle allows obtain a torch significantly superior to torches classics; this superiority of the torch according to the invention being further increased when the surface end 18 of electrode 10 is also provided a second projection 20, so that the rolling of gas shown in Figure 8 is assured.

The embodiment shown in Figures 9 to 11 is similar to that of FIGS. 6 to 8. The electrode 10 however, further comprises at least three grooves 50; in this case, four grooves 50 are shown. These grooves extend radially and cross the crest of the projection 20 thus cutting the contact line 23 which is then discontinuous. As shown in the figure 11, the grooves 50 are distributed along a equiangular arrangement. They cross the surface frustoconical 32 of the bowl as well as the peripheral projection 20.

As shown in Figure 9, when the electrode 10 is applied against the nozzle 12, the flux of plasma gas is not interrupted and continues at through grooves 50. Thus, when the spacing of electrode, a steady stream of plasma gas is established between space 28 and a room 52 delimited in downstream of the conduit 24, between the electrode and the nozzle. In consequence, the electric arc arises in a medium rich in plasma gas. This avoids wall destruction caused by the formation of a metallic plasma. The problems of excessive degradation walls of the electrode and the nozzle are then attenuated by the presence of plasma gas.

In Figures 9 and 10, the gas flow in the annular space 28 takes place axially, so that the gas flow converges radially towards the insert 16. However, as shown in Figure 12, on which the gas flow is represented by a line in propeller 54, the gas can be supplied so vortex, creating a vortex in the annular space 28. This swirling diet promotes stability of the arc root on the insert 16.

In order to further increase the stability of the arc, the grooves 50 may be slightly offset parallel to the radial grooves shown in Figure 11. So as shown in FIG. 13, grooves 50A are offset in the clockwise, so one of the edges of the grooves extends tangentially to the insert emissive 16. So the plasma gas flowing through of these creates at the outlet a vortex flowing in the direction of arrow F1. The gas circulating in space annular 28 forms a vortex circulating in the direction of arrow F2, identical to the direction of arrow F1. So, the root of the electric arc is stabilized by the effect swirling plasma gas streams with senses identical rotation.

On the other hand, in FIG. 14, the grooves 50B are offset parallel to the radial grooves 50 of Figure 11 counterclockwise of a watch, so that the vortex created at the outlet of grooves 50B rotates in the direction of arrow F3 opposite in the sense of circulation of the plasma gas in space annular 28 and indicated by arrow F2.

In this embodiment, the root of the arc is then stabilized by the two vortex flows traveling counter-rotating.

According to Figures 15 and 16, the end of the electrode 10 has a convex frustoconical surface 60 and has in its center the flat face insert 16. The diameter of the electrode is thus gradually decreasing from the diameter of its lateral surface cylindrical up to the outside diameter of the insert 16.

The bottom of the nozzle 12 also has a bowl 62 centered on the X-X axis, hereinafter designated by the sleeve term 62. The axial evacuation duct 24 opens into the center of this sleeve 62.

The surface 64 of the sleeve 62 is substantially tapered. The slope of the surface 64 taken relative to to a transverse plane of the torch is greater than the slope of the surface 60 taken with respect to this same plane. In addition, the diameter of the sleeve 62 is greater than the outside diameter of electrode 10. So, as shown in Figure 15, the electrode 10 enters contact with the nozzle on the surface of the sleeve 62 at the periphery of it along a line of contact circular 66. The electrode 10 is applied to the surface 64 along the line connecting the frustoconical surface 66 to the cylindrical lateral surface of the electrode.

The electric arc arises on the outskirts of the electrode 10 and the nozzle sleeve 12 on an area of small extent. Thus, the entry of the axial duct ejection is preserved from arc attacks electric, the arc being kept away from the conduit.

According to Figures 17 and 18, the bottom of the nozzle 12 is delimited by an axial sleeve 70 formed of two successive frustoconical surfaces 70A, 70B of conicities different.

The electrode 10 has a planar end face 72 whose outside diameter is less than the diameter of the sleeve 70. The insert 16 is flush with the center of this area. Grooves 74 are formed radially on the end surface of the electrode. The end of the electrode has a slightly 76 lateral surface tapered. The grooves 74 open, on the one hand, onto the side wall 76 of the electrode and, on the other hand, on the end face thereof on the outside of the insert 16.

As shown in Figure 17, the contact between the electrode 10 and the nozzle 12 is established between the crest electrode device and the inner surface of the sleeve 70 in the vicinity of the periphery of the surface 70B. When the electrode and the nozzle are in contact, the plasma gas flows through grooves 74, allowing thus the birth of the electric arc in a medium rich in plasma gas. The electrode surfaces and of the nozzle are preserved by maintaining the location of the roots of the nascent electric arc and by the presence of grooves allowing circulation permanent plasma gas.

The torch heads in Figures 15-18, as those of Figures 6 to 14, have, on the bottom of nozzle, of a first axial peripheral projection 40, of so the circulation of the plasma gas stream flowing between the electrode 10 and the nozzle is carried out optimally, i.e. substantially without turbulence.

Claims (11)

Plasma torch head having an electrode axial (10) and a peripheral nozzle (12) whose bottom (22) comprises an axial duct (24) for ejecting the jet of plasma, the electrode (10) and the nozzle (12) being axially movable relative to each other in view of their temporary contact along a surface of contact (23) to initiate an electric arc between the electrode (10) and the nozzle (12), characterized in that that the bottom (22) of the nozzle (12) has a first axial peripheral projection (40). Plasma torch head according to claim 1, characterized in that the contact surface (23) between the bottom (22) of the nozzle and the electrode (10) is well away from the inlet of the axial ejection duct (24) of the nozzle. Plasma torch head according to one of the claims 1 to 2, characterized in that one side end (18) of the electrode (10) has a second axial peripheral projection (20) defining the surface contact (23). Plasma torch head according to one of the Claims 1 to 3, characterized in that the surface contact (23) is at least one contact line continuous or discontinuous. Plasma torch head according to one of the Claims 1 to 4, characterized in that the face end (18) of the electrode comprises a cup (30) axial delimited by a surface (32) which is connected tangentially to the second peripheral projection (20) bordering the bowl. Plasma torch head according to one of the Claims 1 to 5, characterized in that the duct axial ejection (24) opens at the top of the first projection (40), the contact line (23) being established substantially at the base of the first projection (40). Plasma torch head according to claim 6, characterized in that the profile of the first projection (40) corresponds substantially to the profile of the axial cup (30). Plasma torch head according to one of the Claims 1 to 7, characterized in that the surfaces the axial bowl (30) and the first projection (40) are substantially frustoconical and in that the slope of the surface of the axial bowl (30) taken relative to a transverse plane of the torch is greater than the slope of the surface of the first projection (40) taken by report on the transversal plan. Plasma torch head according to one of the Claims 1 to 8, characterized in that the surfaces frustoconical (32, 42) are connected at their periphery outside tangentially to the adjacent surfaces the extending. Plasma torch head according to any one of claims 1 to 9, characterized in that the the contact surface (23) is crossed by grooves (50, 50A, 50B) substantially radial. Plasma torch head according to any one claims 1 to 10, characterized in that said electrode (10) has a flat face insert (16) arranged axially and flush with its end face.

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