Title of Invention	A METHOD AND A DEVICE FOR MANUFACTURING A SPARK EROSION ELECTRODE AND THE ELECTRODE WIRE
Abstract	«A METHOD AND A DEVICE FOR MANUFACTURING A SPARK EROSION ELECTRODE AND THE ELECTRODE WIRE11 A conductor wire (1) is passed through a bath (3) of molten metal in a container (2) . While it is passing through the bath (3) of molten metal, the wire is heated by the Joule effect by an electric current produced by a current source (12) . This improves the adhesion of the metallic surface layer deposited on the core of the wire, so that the wire can be drawn directly by dies (11) downstream of the bath (3) of molten metal. This provides a fast and low-cost method of manufacturing a spark erosion electrode wire.

Title of Invention

A METHOD AND A DEVICE FOR MANUFACTURING A SPARK EROSION ELECTRODE AND THE ELECTRODE WIRE

Abstract

«A METHOD AND A DEVICE FOR MANUFACTURING A SPARK EROSION ELECTRODE AND THE ELECTRODE WIRE11 A conductor wire (1) is passed through a bath (3) of molten metal in a container (2) . While it is passing through the bath (3) of molten metal, the wire is heated by the Joule effect by an electric current produced by a current source (12) . This improves the adhesion of the metallic surface layer deposited on the core of the wire, so that the wire can be drawn directly by dies (11) downstream of the bath (3) of molten metal. This provides a fast and low-cost method of manufacturing a spark erosion electrode wire.

Full Text	The present invention concerns a method and a device for manufacturing a spark erosion electrode and the electrode wire used in the machining of metal parts by the spark erosion process. In such machining, as described in document FR-A-2 418 699, for example, a wire electrode is driven in longitudinal translation and a portion of said wire is guided and stretched along a straight line segment that is displaced laterally along a path near a metal part to be machined. An electrical generator produces a potential difference between the part to be machined and the metal wire forming the electrode. Machining occurs in the machining area between the electrode wire and the metal part and progressively erodes the part and the wire. It has been a long-standing aim to improve the qualities of spark erosion electrode wire by combining good mechanical tensile strength, good electrical conductivity of the wire and more regular production of erosive sparks in the machining area between the electrode wire and the part to be machined. For example, document US-A- 4 287 404 describes a method and a device for manufacturing a spark erosion electrode wire having a filamentary core surrounded by a layer of metal having a low boiling point, such as zinc, cadmium, tin, lead, antimony or bismuth. The metallic surface layer is deposited by an electrolytic deposition step followed by a wire drawing step. A method of this kind has the drawback of producing an electrode wire with a surface layer that vaporizes too quickly and provides insufficient protection of the core during spark erosion. It has been found advantageous to heat the wire after electrolytic deposition of the surface layer of metal having a low boiling point, as taught in document EP-A-185 492, in order to produce a diffused alloy. However, a method of this kind cannot produce at high speed an electrode wire having a thick surface layer of diffused alloy. Document US-A-4 169 426 describes another method of manufacturing a spark erosion electrode wire having a filamentary core surrounded by a metal layer in which an input conductive wire is passed continuously through a bath of molten metal, after which the wire is rapidly cooled to avoid the formation of intermetallic compounds at the interface between the filamentary core and the metallic surface layer. The wire is then heat treated at 32 0 °C for several minutes before it is drawn down to the required final diameter. A method of this kind also has the drawback that it is slow, in particular because of the heat treatment time needed to enable subsequent wire drawing without damaging the metallic surface layer. Document CH-A-655 265 proposes to preheat the input conductive wire by the Joule effect, by passing an appropriate electric current through it, before it is passed through a bath of molten metal. The aim is to increase the speed of manufacture of the spark erosion wire. On leaving the bath of molten metal, the wire is cooled rapidly to prevent the formation of intermetallic compounds at the interface between the core and the coating. The wire can then be drawn down to the required final diameter. This document clearly teaches that the wire drawing is possible because no intermetallic compounds are formed at the interface between the core and the coating. However, it is very difficult to carry out wire drawing afterwards without seriously damaging the metallic surface layer. This layer tends to become j detached from the core because of the mechanical stresses ; applied by the wire drawing die. Documents US-A-3 391 450 and FR-A-1 526 442 describe a combined method of annealing and tinning a copper wire in which the annealing is done by passing an electric current through the wire before, during and after its passage through a bath of molten tin at a relatively low temperature, the wire being heated by the current to a temperature close to that of the bath of molten tin. There is no mention of wire drawing, of applications to spark erosion or of problems with adhesion of the metallic surface layer. The problem addressed by the present invention is therefore that of designing simple and inexpensive means for improving the adhesion of the metallic surface layer to the filamentary core in a fast method of manufacturing spark erosion electrode wire passing continuously through a bath of molten metal in order to enable subsequent drawing of the wire without significant damage to the metallic surface layer. The aim is thus to produce at high speed a spark erosion electrode wire having a thick surface layer of diffused alloy. The invention stems from the surprising observation that the adhesion of the metallic layer to the central core is considerably improved if the wire is heated sufficiently by the Joule effect during its passage through the bath of molten metal. This goes directly against the teaching of documents US-A-4 169 426 and CH-A-6 55 265 which recommend minimal heating of the filamentary core to prevent the formation of intermetallic compounds at the interface between the core and the metallic surface layer. SUMMARY OF THE INVENTION Accordingly, to achieve the above and other obj ectives, the invention proposes a method of manufacturing a spark erosion electrode wire having a filamentary core surrounded by a metallic layer wherein an inlet conductor wire is caused to pass continuously through a bath of molten metal having low melting and boiling points, after which the wire is cooled and drawn to the required diameter, and, while it is passing through the bath of molten metal, the wire is heated by the Joule effect by causing an appropriate electric current to flow through the wire section passing through the bath of molten metal. In one advantageous embodiment, heating of the wire by the Joule effect is continued after the wire leaves the bath of molten metal by passing an electric current through an appropriate section of the wire downstream of the bath of molten metal. Good results are also obtained by further preheating the wire by the Joule effect by passing an electric current through an appropriate section of the wire upstream of the bath of molten metal. For simplicity, the electric current flowing through the upstream section and/or the downstream section of the wire can be the same as the electric current flowing through the bath of molten metal. The method applies to a bath of molten zinc or zinc alloy, for example. The zinc alloy can contain aluminum or copper, for example. A device for manufacturing a spark erosion electrode wire having a filamentary core surrounded by a metallic layer, using a method of the above kind, comprises: - a container adapted to contain a bath of molten metal and to enable a conductive wire to be passed continuously through the bath of molten metal, - wire guide and drive means for guiding the wire and driving it through the bath of molten metal, - means for extruding the wire downstream of the container of the bath of molten metal, characterized in that it further comprises a source of electric current and conductors coming into contact with the wire upstream and downstream of the container of the bath of molten metal to pass an appropriate electric current through the wire while it is passing through the bath of molten metal in order to heat said wire by the Joule effect. An electrode wire made by a method as described above having a thick surface layer of diffused zinc alloy. Other objects, features and advantages of the present invention will emerge from the following description of particular embodiments given with reference to the accompanying drawings. Figure 1 is a diagrammatic representation of a device for producing a spark erosion electrode wire in one embodiment of the present invention. Figure 2 is a perspective view showing diagramatically a section of spark erosion electrode wire of the invention. In the embodiment shown in figure 1, a device of the invention for manufacturing a spark erosion electrode wire 1 includes a container 2 adapted to contain a bath 3 of molten metal. Heating means, not shown, maintain the bath at an appropriate temperature to keep the metal molten during the manufacture of the wire 1. The container 2 has an inlet orifice 4 and an outlet orifice 5 to enable a conductive wire to pass continuously through the bath 3 of molten metal, preferably in the upward direction. Means for guiding and driving the wire guide the wire 1 and drive it in continuously longitudinal translation through the bath 3 of molten metal. For example, the wire 1 is delivered from an upstream spool 6 to a downstream spool 7, passing over jockey pulleys 8, 9 and 10 and through the bath 3 of molten metal between the inlet orifice 4 and the outlet orifice 5 of the container 2. The device further includes one or more dies 11 for extruding the wire 1 after it passes through the container 2 and before it is wound onto the downstream spool 7. The device also includes a source 12 of electric current connected to conductors 13 and 14 coming into contact with the wire 1 at a point A upstream of the container 2 and at a point D downstream of the container 2, respectively. The current source 12 causes an appropriate electric current to flow through the wire 1 as it passes through the bath 3 of molten metal, causing additional heating of the wire 1 by the Joule effect. The additional heating of the wire 1 by the Joule effect preferably heats the peripheral part of the wire 1 to a sufficiently high temperature to prevent the formation of fragile alloy phases at the interface between the core 16 of the wire and its coating 15. In the case of a copper wire coated with zinc, for example, this avoids the formation of y, 8 or s phases that can make the interface fragile. The appropriate electric current can advantageously be such that the wire 1 is substantially at red heat during its passage through the bath 3 of molten metal. In a first embodiment the upstream point of contact A is in the immediate proximity of the inlet orifice 4 of the container 2 and the downstream contact point D is in the immediate proximity of the outlet orifice 5 of the container 2. In this case, the additional heating of the wire 1 by the Joule effect occurs only in the section BC of the wire passing through the container 2 containing the bath 3 of molten metal. The contact point D can advantageously be moved away from the outlet orifice 5 of the container 2, to continue the heating of the wire 1 by the Joule effect after it leaves the bath 3 of molten metal, thus causing the electric current to flow in the section CD of the wire downstream of the bath 3 of molten metal. The length of the wire section CD can be chosen to heat the wire for a sufficient time to bring about interdiffusion of the coating metal on the surface and the metal constituting the filamentary core. In this embodiment, the electric current flowing through the downstream wire section CD is the same as the electric current flowing through the bath 3 of molten metal. As an alternative to this, an electrical circuit can naturally be designed to pass a different current through the downstream section CD. The wire can advantageously be preheated by the Joule effect by moving the upstream point of contact A away from the inlet orifice 4, In this way an electric current is caused to flow in an appropriate section AB of the wire upstream of the bath 3 of molten metal. In this embodiment, the electric current flowing through the upstream wire section AB is the same as the electric current flowing through the bath 3 of molten metal. Alternatively, electric contacts can be designed to pass a different electric current through the upstream wire section AB. When a device of this kind from figure 1 is in use, an inlet conductive wire wound on the upstream spool 6 is paid off from the upstream spool 6, passes over the first jockey pulley 8 and then comes into contact with the conductor 13 at the point A. The electrical current from the current generator 12 then flows in the upstream wire section AB and heats the wire by the Joule effect so that the wire is already at a high temperature when it enters the container 2 through the inlet orifice 4. As it passes through the container 2 containing a bath 3 of molten metal, the output current of the generator 12 also flows through the wire, said current extending the heating of the wire by the Joule effect. When it passes through the bath 3 of molten metal the wire picks up a surface layer of molten metal. Heating by the Joule effect continues along the downstream section CD, as far as the downstream point of contact D with the conductor 14. The wire then cools, after which it enters the die or dies 11 in which it is extruded to the required final diameter. The extruded wire is wound onto the downstream spool 7. The electrode wire of the invention is therefore manufactured by passing the wire 1 continuously through a bath 3 of molten metal having a low boiling point and a high vapor pressure, after which the wire is cooled and drawn to the required diameter. While it is passing through the bath 3 of molten metal, the wire is heated by the Joule effect by passing an appropriate electric current through the wire section BC passing through the bath 3 of molten metal. A method of this kind is found to improve significantly the adhesion of the thick metallic surface layer of metal deposited on the core during passage through the bath 3 of molten metal with the result that the metallic surface layer is not damaged on passing through the wire drawing dies 11. The molten metal in the bath 3 of molten metal can „-"*be zinc or zinc alloy. For example, the molten metal can be an alloy of zinc and at least on other metal such aluminum or copper. The core of the wire, formed by the inlet conductive wire paid off from the upstream spool 6, can be of copper or copper alloy, for example. In the embodiment shown in figure 2, an electrode wire made by a method as previously described has a thick surface layer 15 of zinc diffused alloy around a core 16. The core 16 can be of copper or copper alloy, for example. Thanks to the good adhesion of the metallic surface layer to the core, sizing of the wire by the dies 11 can take place at the same speed as the wire passes through the bath 3 of molten metal. This yields a particularly fast and low-cost process for manufacturing a spark erosion electrode wire. The present invention is not limited to the embodiments that have just be explicitly described, but encompasses the various variants and generalizations thereof contained within the scope of the following claims. WE CLAIM. 1. Method of manufacturing a spark erosion electrode wire (1) having a filamentary core (16) surrounded by a metallic layer (15) wherein an inlet conductor wire is caused to pass continuously through a bath (3) of molten metal having low melting and boiling points, after which the wire (1) is cooled and drawn to the required diameter, characterized in that, while it is passing through the bath (3) of molten metal, the wire (1) is heated by the Joule effect by causing an appropriate electric current to flow through the wire section (BC) passing through the bath (3) of molten metal. 2. Method according to claim 1 characterized in that heating of the wire (1) by the Joule effect is continued after the wire (1) leaves the bath (3) of molten metal by passing an electric current through an appropriate section (CD) of the wire (1) downstream of the bath (3) of molten metal. 3. Method according to claim 2 characterized in that the electric current flowing through the downstream wire section (CD) is the same as the electric current flowing through the bath (3) of molten metal. 4. Method according to any one of claims 1 to 3 characterized in that the wire is preheated by the Joule effect by passing an electric current through an appropriate section (AB) of the wire upstream of the bath (3) of molten metal. 5. Method according to claim 4 characterized in that the electric current flowing through the upstream wire section (AB) is the same as the electric current flowing through the bath (3) of molten metal. 6. Method according to any one of claims 1 to 5 characterized in that the molten metal is zinc or zinc alloy. 7. Method according to claim 6 characterized in that the molten metal is an alloy of zinc and at least one other metal such as aluminum or copper. 8. Method according to any one of claims 1 to 7 characterized in that the appropriate electric current is such that the wire (1) is substantially at red heat while passing through the bath (3) of molten metal. 9. Device for manufacturing a spark erosion electrode wire (1) having a filamentary core (16) surrounded by a metallic layer (15), comprising: - a container (2) adapted to contain a bath (3) of molten metal and to enable a conductive wire (1) to be passed continuously through the bath (3) of molten metal, - wire guide and drive means (6, 7, 8, 9, 10, 4, 5) for guiding the wire (1) and driving it through the bath (3) of molten metal, - means (11) for extruding the wire (1) downstream of the container (2) of the bath (3) of molten metal, characterized in that it further comprises a source (12) of electric current and conductors (13, 14) coming into contact with the wire (1) upstream (A) and downstream (D) of the container (2) of the bath (3) of molten metal to pass an appropriate electric current through the wire (1) while it is passing through the bath (3) of molten metal in order to heat said wire (1) by the Joule effect. 10. Device according to claim 9 characterized in that the conductors (13, 14) come into contact with the wire upstream (A) and/or downstream (D) at a distance from the container (2) in order to procure further heating by the Joule effect of the wire (1) upstream and/or downstream of its passage through the bath (3) of molten metal. 11. Electrode wire made by a method according to any one of claims 1 to 10 having a thick surface layer (15) of diffused zinc alloy. 12. Electrode wire according to claim 11 characterized in that it has a copper or copper alloy core (16).

Full Text

The present invention concerns a method and a device for manufacturing a spark erosion electrode and the electrode wire used in the machining of metal parts by the spark erosion process.
In such machining, as described in document FR-A-2 418 699, for example, a wire electrode is driven in longitudinal translation and a portion of said wire is guided and stretched along a straight line segment that is displaced laterally along a path near a metal part to be machined. An electrical generator produces a potential difference between the part to be machined and the metal wire forming the electrode. Machining occurs in the machining area between the electrode wire and the metal part and progressively erodes the part and the wire.
It has been a long-standing aim to improve the qualities of spark erosion electrode wire by combining good mechanical tensile strength, good electrical conductivity of the wire and more regular production of erosive sparks in the machining area between the electrode wire and the part to be machined.
For example, document US-A- 4 287 404 describes a method and a device for manufacturing a spark erosion electrode wire having a filamentary core surrounded by a layer of metal having a low boiling point, such as zinc, cadmium, tin, lead, antimony or bismuth. The metallic surface layer is deposited by an electrolytic deposition step followed by a wire drawing step. A method of this kind has the drawback of producing an electrode wire with a surface layer that vaporizes too quickly and provides insufficient protection of the core during spark erosion.

It has been found advantageous to heat the wire after electrolytic deposition of the surface layer of metal having a low boiling point, as taught in document EP-A-185 492, in order to produce a diffused alloy. However, a method of this kind cannot produce at high speed an electrode wire having a thick surface layer of diffused alloy.
Document US-A-4 169 426 describes another method of manufacturing a spark erosion electrode wire having a filamentary core surrounded by a metal layer in which an input conductive wire is passed continuously through a bath of molten metal, after which the wire is rapidly cooled to avoid the formation of intermetallic compounds at the interface between the filamentary core and the metallic surface layer. The wire is then heat treated at 32 0 °C for several minutes before it is drawn down to the required final diameter. A method of this kind also has the drawback that it is slow, in particular because of the heat treatment time needed to enable subsequent wire drawing without damaging the metallic surface layer.
Document CH-A-655 265 proposes to preheat the input conductive wire by the Joule effect, by passing an appropriate electric current through it, before it is passed through a bath of molten metal. The aim is to increase the speed of manufacture of the spark erosion wire. On leaving the bath of molten metal, the wire is cooled rapidly to prevent the formation of intermetallic compounds at the interface between the core and the coating. The wire can then be drawn down to the required final diameter. This document clearly teaches that the wire drawing is possible because no intermetallic compounds are formed at the interface between the core and the coating.
However, it is very difficult to carry out wire drawing afterwards without seriously damaging the

metallic surface layer. This layer tends to become j detached from the core because of the mechanical stresses ; applied by the wire drawing die.
Documents US-A-3 391 450 and FR-A-1 526 442 describe a combined method of annealing and tinning a copper wire in which the annealing is done by passing an electric current through the wire before, during and after its passage through a bath of molten tin at a relatively low temperature, the wire being heated by the current to a temperature close to that of the bath of molten tin. There is no mention of wire drawing, of applications to spark erosion or of problems with adhesion of the metallic surface layer.
The problem addressed by the present invention is therefore that of designing simple and inexpensive means for improving the adhesion of the metallic surface layer to the filamentary core in a fast method of manufacturing spark erosion electrode wire passing continuously through a bath of molten metal in order to enable subsequent drawing of the wire without significant damage to the metallic surface layer. The aim is thus to produce at high speed a spark erosion electrode wire having a thick surface layer of diffused alloy.
The invention stems from the surprising observation that the adhesion of the metallic layer to the central core is considerably improved if the wire is heated sufficiently by the Joule effect during its passage through the bath of molten metal.
This goes directly against the teaching of documents US-A-4 169 426 and CH-A-6 55 265 which recommend minimal heating of the filamentary core to prevent the formation of intermetallic compounds at the interface between the core and the metallic surface layer. SUMMARY OF THE INVENTION
Accordingly, to achieve the above and other

obj ectives, the invention proposes a method of manufacturing a spark erosion electrode wire having a filamentary core surrounded by a metallic layer wherein an inlet conductor wire is caused to pass continuously through a bath of molten metal having low melting and boiling points, after which the wire is cooled and drawn to the required diameter, and, while it is passing through the bath of molten metal, the wire is heated by the Joule effect by causing an appropriate electric current to flow through the wire section passing through the bath of molten metal.
In one advantageous embodiment, heating of the wire by the Joule effect is continued after the wire leaves the bath of molten metal by passing an electric current through an appropriate section of the wire downstream of the bath of molten metal.
Good results are also obtained by further preheating the wire by the Joule effect by passing an electric current through an appropriate section of the wire upstream of the bath of molten metal.
For simplicity, the electric current flowing through the upstream section and/or the downstream section of the wire can be the same as the electric current flowing through the bath of molten metal.
The method applies to a bath of molten zinc or zinc alloy, for example.
The zinc alloy can contain aluminum or copper, for example.
A device for manufacturing a spark erosion electrode wire having a filamentary core surrounded by a metallic layer, using a method of the above kind, comprises:
- a container adapted to contain a bath of molten metal and to enable a conductive wire to be passed continuously through the bath of molten metal,

- wire guide and drive means for guiding the wire and driving it through the bath of molten metal,
- means for extruding the wire downstream of the container of the bath of molten metal,
characterized in that it further comprises a source of electric current and conductors coming into contact with the wire upstream and downstream of the container of the bath of molten metal to pass an appropriate electric current through the wire while it is passing through the bath of molten metal in order to heat said wire by the Joule effect.
An electrode wire made by a method as described above having a thick surface layer of diffused zinc alloy.
Other objects, features and advantages of the present invention will emerge from the following description of particular embodiments given with reference to the accompanying drawings.
Figure 1 is a diagrammatic representation of a device for producing a spark erosion electrode wire in one embodiment of the present invention.
Figure 2 is a perspective view showing diagramatically a section of spark erosion electrode wire of the invention.
In the embodiment shown in figure 1, a device of the invention for manufacturing a spark erosion electrode wire 1 includes a container 2 adapted to contain a bath 3 of molten metal. Heating means, not shown, maintain the bath at an appropriate temperature to keep the metal molten during the manufacture of the wire 1. The container 2 has an inlet orifice 4 and an outlet orifice 5 to enable a conductive wire to pass continuously through the bath 3 of molten metal, preferably in the upward direction.
Means for guiding and driving the wire guide the wire 1 and drive it in continuously longitudinal translation through the bath 3 of molten metal. For

example, the wire 1 is delivered from an upstream spool 6 to a downstream spool 7, passing over jockey pulleys 8, 9 and 10 and through the bath 3 of molten metal between the inlet orifice 4 and the outlet orifice 5 of the container 2.
The device further includes one or more dies 11 for extruding the wire 1 after it passes through the container 2 and before it is wound onto the downstream spool 7.
The device also includes a source 12 of electric current connected to conductors 13 and 14 coming into contact with the wire 1 at a point A upstream of the container 2 and at a point D downstream of the container 2, respectively. The current source 12 causes an appropriate electric current to flow through the wire 1 as it passes through the bath 3 of molten metal, causing additional heating of the wire 1 by the Joule effect.
The additional heating of the wire 1 by the Joule effect preferably heats the peripheral part of the wire 1 to a sufficiently high temperature to prevent the formation of fragile alloy phases at the interface between the core 16 of the wire and its coating 15. In the case of a copper wire coated with zinc, for example, this avoids the formation of y, 8 or s phases that can make the interface fragile.
The appropriate electric current can advantageously be such that the wire 1 is substantially at red heat during its passage through the bath 3 of molten metal.
In a first embodiment the upstream point of contact A is in the immediate proximity of the inlet orifice 4 of the container 2 and the downstream contact point D is in the immediate proximity of the outlet orifice 5 of the container 2. In this case, the additional heating of the wire 1 by the Joule effect occurs only in the section BC of the wire passing through

the container 2 containing the bath 3 of molten metal.
The contact point D can advantageously be moved away from the outlet orifice 5 of the container 2, to continue the heating of the wire 1 by the Joule effect after it leaves the bath 3 of molten metal, thus causing the electric current to flow in the section CD of the wire downstream of the bath 3 of molten metal. The length of the wire section CD can be chosen to heat the wire for a sufficient time to bring about interdiffusion of the coating metal on the surface and the metal constituting the filamentary core.
In this embodiment, the electric current flowing through the downstream wire section CD is the same as the electric current flowing through the bath 3 of molten metal. As an alternative to this, an electrical circuit can naturally be designed to pass a different current through the downstream section CD.
The wire can advantageously be preheated by the Joule effect by moving the upstream point of contact A away from the inlet orifice 4, In this way an electric current is caused to flow in an appropriate section AB of the wire upstream of the bath 3 of molten metal.
In this embodiment, the electric current flowing through the upstream wire section AB is the same as the electric current flowing through the bath 3 of molten metal. Alternatively, electric contacts can be designed to pass a different electric current through the upstream wire section AB.
When a device of this kind from figure 1 is in use, an inlet conductive wire wound on the upstream spool 6 is paid off from the upstream spool 6, passes over the first jockey pulley 8 and then comes into contact with the conductor 13 at the point A. The electrical current from the current generator 12 then flows in the upstream wire section AB and heats the wire by the Joule effect so that

the wire is already at a high temperature when it enters the container 2 through the inlet orifice 4. As it passes through the container 2 containing a bath 3 of molten metal, the output current of the generator 12 also flows through the wire, said current extending the heating of the wire by the Joule effect. When it passes through the bath 3 of molten metal the wire picks up a surface layer of molten metal. Heating by the Joule effect continues along the downstream section CD, as far as the downstream point of contact D with the conductor 14. The wire then cools, after which it enters the die or dies 11 in which it is extruded to the required final diameter. The extruded wire is wound onto the downstream spool 7.
The electrode wire of the invention is therefore manufactured by passing the wire 1 continuously through a bath 3 of molten metal having a low boiling point and a high vapor pressure, after which the wire is cooled and drawn to the required diameter. While it is passing through the bath 3 of molten metal, the wire is heated by the Joule effect by passing an appropriate electric current through the wire section BC passing through the bath 3 of molten metal. A method of this kind is found to improve significantly the adhesion of the thick metallic surface layer of metal deposited on the core during passage through the bath 3 of molten metal with the result that the metallic surface layer is not damaged on passing through the wire drawing dies 11.
The molten metal in the bath 3 of molten metal can „-"*be zinc or zinc alloy.
For example, the molten metal can be an alloy of zinc and at least on other metal such aluminum or copper.
The core of the wire, formed by the inlet conductive wire paid off from the upstream spool 6, can be of copper or copper alloy, for example.

In the embodiment shown in figure 2, an electrode wire made by a method as previously described has a thick surface layer 15 of zinc diffused alloy around a core 16. The core 16 can be of copper or copper alloy, for example.
Thanks to the good adhesion of the metallic surface layer to the core, sizing of the wire by the dies 11 can take place at the same speed as the wire passes through the bath 3 of molten metal. This yields a particularly fast and low-cost process for manufacturing a spark erosion electrode wire.
The present invention is not limited to the embodiments that have just be explicitly described, but encompasses the various variants and generalizations thereof contained within the scope of the following claims.

WE CLAIM.
1. Method of manufacturing a spark erosion
electrode wire (1) having a filamentary core (16)
surrounded by a metallic layer (15) wherein an inlet
conductor wire is caused to pass continuously through a
bath (3) of molten metal having low melting and boiling
points, after which the wire (1) is cooled and drawn to
the required diameter, characterized in that, while it is
passing through the bath (3) of molten metal, the wire
(1) is heated by the Joule effect by causing an appropriate electric current to flow through the wire section (BC) passing through the bath (3) of molten metal.
2. Method according to claim 1 characterized in that heating of the wire (1) by the Joule effect is continued after the wire (1) leaves the bath (3) of molten metal by passing an electric current through an appropriate section (CD) of the wire (1) downstream of the bath (3) of molten metal.
3. Method according to claim 2 characterized in that the electric current flowing through the downstream wire section (CD) is the same as the electric current flowing through the bath (3) of molten metal.
4. Method according to any one of claims 1 to 3 characterized in that the wire is preheated by the Joule effect by passing an electric current through an appropriate section (AB) of the wire upstream of the bath
(3) of molten metal.
5. Method according to claim 4 characterized in
that the electric current flowing through the upstream
wire section (AB) is the same as the electric current
flowing through the bath (3) of molten metal.
6. Method according to any one of claims 1 to 5
characterized in that the molten metal is zinc or zinc
alloy.

7. Method according to claim 6 characterized in that the molten metal is an alloy of zinc and at least one other metal such as aluminum or copper.
8. Method according to any one of claims 1 to 7 characterized in that the appropriate electric current is such that the wire (1) is substantially at red heat while passing through the bath (3) of molten metal.
9. Device for manufacturing a spark erosion electrode wire (1) having a filamentary core (16) surrounded by a metallic layer (15), comprising:

- a container (2) adapted to contain a bath (3) of molten metal and to enable a conductive wire (1) to be passed continuously through the bath (3) of molten metal,
- wire guide and drive means (6, 7, 8, 9, 10, 4, 5) for guiding the wire (1) and driving it through the bath (3) of molten metal,
- means (11) for extruding the wire (1) downstream of the container (2) of the bath (3) of molten metal,
characterized in that it further comprises a source (12) of electric current and conductors (13, 14) coming into contact with the wire (1) upstream (A) and downstream (D) of the container (2) of the bath (3) of molten metal to pass an appropriate electric current through the wire (1) while it is passing through the bath (3) of molten metal in order to heat said wire (1) by the Joule effect.
10. Device according to claim 9 characterized in that the conductors (13, 14) come into contact with the wire upstream (A) and/or downstream (D) at a distance from the container (2) in order to procure further heating by the Joule effect of the wire (1) upstream and/or downstream of its passage through the bath (3) of molten metal.
11. Electrode wire made by a method according to any one of claims 1 to 10 having a thick surface layer

(15) of diffused zinc alloy.
12. Electrode wire according to claim 11 characterized in that it has a copper or copper alloy core (16).

Documents:

1074-mas-1997- abstract.pdf

1074-mas-1997- claims duplicate.pdf

1074-mas-1997- claims original.pdf

1074-mas-1997- correspondence others.pdf

1074-mas-1997- correspondence po.pdf

1074-mas-1997- description complete duplicate.pdf

1074-mas-1997- description complete original.pdf

1074-mas-1997- drawings.pdf

1074-mas-1997- form 1.pdf

1074-mas-1997- form 19.pdf

1074-mas-1997- form 26.pdf

1074-mas-1997- form 3.pdf

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Patent Number

207789

Indian Patent Application Number

1074/MAS/1997

PG Journal Number

27/2007

Publication Date

06-Jul-2007

Grant Date

27-Jun-2007

Date of Filing

21-May-1997

Name of Patentee

M/S. THERMOCOMPACT

Applicant Address

ZONE INDUSTRIALLE LES ILES, 74370 METZ TESSY.

Inventors:

#	Inventor's Name	Inventor's Address
1	LACOURCELLE LOUIS	34700 SAIT JEAN DE LA BLAQUIERE.

PCT International Classification Number

EP0811701A1

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	96 07026	1996-06-04	France