FR2923405A1 - LASER WELDING OF ZINC COATED PARTS - Google Patents

Abstract

A method of laser beam welding of a zinc coated metal part with at least a second metal part, wherein the parts are positioned in contact or near contact with one another so that there is no or almost no play between the said pieces; the weld bead is made by melting the metal with the formation of a capillary or keyhole filled with metal vapors immediately downstream of the point of impact of the beam on the part or parts; and directing a first gas flow only towards the opening of the metal vapor capillary so as to exert a sufficient gaseous dynamic pressure therein to maintain the capillary sufficiently open to evacuate at least a portion of the zinc vapors from the surface coating, during all the time of relative movement of the laser beam relative to the parts. This process is particularly suitable for welding parts for the automotive industry.

Description

The invention relates to the field of laser beam welding of zinc-coated parts used in particular for the manufacture of motor vehicles.

The laser beam welding of zinc-coated sheets, widely used for the construction of motor vehicles, is difficult to implement because of the presence of the zinc layer on the parts to be welded. Indeed, most of the assemblies are made by transparency, that is to say that the coated sheets are first placed one above the other and then we focus the laser perpendicularly to the interface of the two sheets. In this case, the zinc present at the interface vaporizes violently and can induce welding bath explosions, as well as significant porosities in the weld bead. The solutions used today to overcome these problems are not entirely satisfactory.

Indeed, a first possibility is to create a constant play at the interface of the parts that will allow the zinc vaporized by the beam, to escape during the welding operation. However, it is very difficult in practice to maintain this game constant and, most often, it is actually a game variable, so sometimes zero or the opposite, important.

However, when this game is zero, the welding goes badly for the reasons mentioned above, when, when this game is too important, we then witness a collapse of the weld bead because the game is too important for the molten metal can come and fill it. Most of the focusing heads equipped with a pressure finger, namely a wheel 25 which comes more or less strongly on the sheets to be welded in front of the laser, also do not solve this problem. Moreover, it has already been proposed to use particular gas mixtures to try to minimize these problems. Thus, EP-A-527229 proposes to use a gaseous mixture based on argon and oxygen, whereas US-A-5,831,239 proposes to use a mixture formed of an oxidizing gas, such as a mixture of oxygen with nitrogen, helium or argon, and dry air. The oxygen present in these gas mixtures is supposed to go oxidize and burn the zinc vapors that are produced during the welding and thus avoid the porosities.

That said, these processes lead to the following drawbacks, namely, on the one hand, they require the use of specific gas mixtures and sometimes difficult to implement, and on the other hand, the vaporization of zinc is so violent that in general it is quite difficult to prevent even with gaseous mixtures of this type.

A problem that arises is therefore to propose an effective laser welding process for zinc-coated parts, in particular those made of coated steel used for the construction of motor vehicles, which does not have the above drawbacks, in particular which does not require a space or clearance between the parts to be welded, that is to say that the parts can be arranged in contact or in quasi-contact with respect to each other so that there is no, almost no play or very low play (ie at most 0.15 to 0.20 mm) between said pieces in the region where the weld bead is to be made. The solution of the invention is then a laser beam welding process of at least a first metal part coated with zinc with at least one second metal part, in which: a) positioning at least a first coated metal part on to at least a part of one of its surfaces of a zinc layer with respect to at least a second metal part so as to obtain an assembly to be welded, and b) a melting of at least a part of the constituent metal is carried out said parts, by means of at least one laser beam striking at least one of said parts and at least a part of the surface coating containing zinc, and moving said laser beam relative to said assembly along a desired welding path so as to create a weld bead between said parts forming said assembly along said welding path and to cause a vaporization of at least a portion of the zinc co embedded image in said surface coating, characterized in that: - in step a), the parts are positioned in contact or in quasi-contact relative to each other so that there is no or almost no clearance between said parts in the region where the weld bead must be made according to the desired welding path, and - in step b), the weld bead is made by melting the metal with formation of a capillary or keyhole filled with metal vapors immediately downstream of the point of impact of the beam on the part or parts, and a first flow of gas is directed towards the opening of the metal vapor capillary so as to exert a sufficient gaseous dynamic pressure therein to maintain the capillary sufficiently open to evacuate at least a portion of the zinc vapors from the surface coating during the entire period of relative movement of the laser beam relative to the surface these.

In other words, according to the invention, the gaseous dynamic pressure sufficient to keep the capillary open and thus evacuate at least a portion of the zinc vapors from the surface coating, which it is not possible to obtain usually welding when the parts are positioned in contact or near contact with each other so that there is no or almost no play between them.

Indeed, the inventors of the present invention have shown that when directed towards the opening of the laser welding capillary, a flow of gas distributed by a welding nozzle or nozzle whose diameter was of the order of 1 to 2 mm, and whose typical speed of the gas was of the order of 5 to 6 m / sec, it was possible to open very importantly the vapor capillary without destabilizing the welding bath, and thus allow the vaporized zinc of s' to escape freely without disturbing the welding cord. In fact, when the method of the invention is used, the opening of the capillary is multiplied by a factor greater than 3 and generally between about 5 and 10 with respect to a capillary obtained with a conventional method. Thus, a capillary obtained with a conventional method is slightly larger than the diameter of the focal spot, namely of the order of 500 m, whereas, when the method of the invention is used, its diameter is multiplied by 5 to 10 approximately, that is to say it is about 3 to 5 mm. This can be viewed using a fast camera. Depending on the case, the method of the invention may comprise one or more of the following characteristics: the weld bead is obtained by re-solidification of the molten metal in step b). the first gas stream is used to exert a continuous and substantially constant gaseous dynamic pressure over the opening of the vapor capillary, preferably in a direction perpendicular to the piece (s) to be welded or inclined with respect to the surface of said rooms. the first gas stream is used to stabilize the flow of the molten metal liquid bath. in addition, a second protective gas stream distributed peripherally and / or coaxially with the first gas flow is used. - The flow rate of the first gas is of the order of 10 to 201 / min and the flow rate of the second gas is of the order of 20 to 30 1 / min. - The distribution rate of the first gas is of the order of 2 to 10 m / sec, preferably of the order of 4 to 7 m / sec, preferably of the order of 5 to 6 m / sec. the first and second gases are chosen from argon, helium, nitrogen and their mixtures, and possibly in a smaller proportion of CO2, oxygen or hydrogen, or else with air, including purified air and cleared of ambient impurities that it may contain and which are likely to pollute the weld pool. the laser beam is generated by an Nd: YAG type laser generator, with Ytterbium fiber or CO2. the metal part or parts to be welded are made of zinc coated carbon steel. - The parts are superimposed on one another and the welding is operated by transparency. the welding nozzle delivering the first gas flow has a gas passage section of between 0.1 and 10 mm 2, preferably of 0.5 to 5 mm 2 of cross-section, for example a nozzle with a circular exit orifice of 1 to 2; mm diameter. the pressure of the first gas flow is between 1 and 10 kPa. Figure 1 schematizes the mode of action of this jet of gas. More precisely, it shows the vapor capillary 1 surmounted by metal vapor 2 obtained by melting by the laser beam 3 of the constituent metal of the parts to be welded which are covered with a layer of zinc.

The molten metal is then re-solidified into a weld bead 4. In order to keep the keyhole open and allow good degassing of the zinc, a nozzle 1 of 1 to 2 mm in diameter distributes a first flow of gas under pressure to said keyhole . The flow of gas is directed only towards the opening of the capillary 1 of metal vapor and in a direction perpendicular to the parts to be welded or inclined on one side or the other, so as to exert a sufficient gaseous dynamic pressure to significantly increase the diameter of the capillary, during the entire time of relative movement of the laser beam 3 relative to the parts, and thus allow evacuation of zinc vapors from the surface coating of the parts. In other words, the gas pressure exerted must be sufficient to lead to an evacuation of vaporized zinc by the opening of the capillary. Furthermore, advantageously, a second protective gas stream distributed peripherally and / or coaxially with the first gas flow delivered by the nozzle 5 is also used. Conventionally, this second gas flow serves to protect the welding zone. , in particular the solder bath, atmospheric contaminations, in particular the incorporation into the molten metal of the bath of nitrogen, water vapor or similar impurities which could contaminate this bath by generating defects therein, such as porosities.

It is therefore understood that only the first gas flow delivered by the nozzle exerts a gas pressure on the keyhole, the second gas stream only serves to protect the entire welding zone of the ambient atmosphere, so does not come not to put pressure on the keyhole. The method of the invention thus makes it possible to weld zinc-coated sheets irrespective of the clearance present between the sheets to be welded, in particular this method is applicable to the welding of assemblies in the automotive field, that is to say assemblies of several parts, at least one of which has a galvanized or partly galvanized surface, ie galvanized or electro-galvanized. The weld bead made may be opening, that is to say through the entire thickness to be welded, or not opening depending on the application considered. Figure 2 attached diagrammatically shows different configurations of parts for which the method of the invention can be applied, including stacks of two or three sheets of variable thickness welded by transparency, that is to say that the sheets are at least partially superimposed on each other, and that the laser beam passes through the thickness or part of the thickness of one of the sheets (that located on the side where the beam arrives) before striking and melting the other sheet (the one furthest away from the laser nozzle delivering the beam). These configurations have the particularity of having all, to varying degrees, a zinc-covered surface that during laser welding will vaporize causing the aforementioned defects. However, the method of the invention can weld these configurations without any problem of this type. Specifically, Figures 2a, 2g, 21, 2m and 2n show a clinching weld; Figures 2b and 2i, angled-angle welding; Figure 2c, an angle T welding; Figure 2d, a T welding by transparency; Figures 2e and 2f, soldering on fallen edges; Figure 2h, edge welding; Figure 2j, a corner welding by transparency; and Figure 2k, edge-to-edge corner welding.

Claims (12)

claims A method of laser beam welding of at least a first zinc-coated metal part with at least a second metal part, wherein: a) positioning at least a first metal part coated on at least a part of one of its surfaces with a layer of zinc with respect to at least one second metal part so as to obtain an assembly to be welded, and b) a melting of at least a part of the metal constituting said parts, by means of at least one laser beam striking at least one of said parts and at least a portion of the surface coating containing the zinc, and moving said laser beam relative to said assembly in a desired welding path so as to create a bead of welding between said parts forming said assembly along said welding path and causing a vaporization of at least a portion of the zinc included in said surface coating; ue, characterized in that: - in step a), the parts are positioned in contact or in quasi-contact with each other so that there is no or almost no play between said parts in the region where the weld bead is to be made according to the desired welding path, and - in step b), the welding bead is made by melting the metal with the formation of a capillary or keyhole filled with metal vapors immediately downstream of the point of impact of the beam on the part or parts, and a first flow of gas is directed only towards the opening of the metal vapor capillary so as to exert a sufficient gaseous dynamic pressure to maintain the capillary therein sufficiently open to evacuate at least a portion of the zinc vapors from the surface coating during the entire period of relative movement of the laser beam relative to the parts. 2. Method according to claim 1, characterized in that the first gas flow is used to exert a continuous and constant gaseous dynamic pressure on the opening of the vapor capillary, preferably in a direction perpendicular to the part or parts to welded. 3. Method according to one of claims 1 or 2, characterized in that the first gas stream is used to operate a stabilization of the flow of molten metal liquid bath. 4. Method according to one of claims 1 to 3, characterized in that it implements, in addition, a second protective gas stream distributed peripherally and / or coaxially to the first gas flow. 5. Method according to one of claims 1 to 4, characterized in that the flow rate of the first gas is of the order of 10 to 20 1 / min and the flow rate of the second gas is of the order of 20 to 301 / min. 6. Method according to one of claims 1 to 5, characterized in that the nozzle is a coaxial nozzle. 7. Method according to one of claims 1 to 6, characterized in that the first and the second gas are chosen from argon, helium, nitrogen and mixtures thereof, and possibly in a smaller proportion of CO2, oxygen or hydrogen. 20 8. Method according to one of claims 1 to 7, characterized in that the laser beam is generated by a Nd: YAG type laser generator, Ytterbium fiber or CO2. 9. Method according to one of claims 1 to 8, characterized in that the or the metal parts to be welded are zinc-coated carbon steel. 10. Method according to one of claims 1 to 9, characterized in that the parts are superimposed on one another and the welding is operated by transparency. 11. Method according to one of claims 1 to 10, characterized in that the welding nozzle delivering the first gas stream has a gas passage section of between 0.1 and 10 mm. 25 12. Method according to one of claims 1 to 11, characterized in that the pressure of the first gas flow is between 1 and 10 kPa. 5