阅读说明：本技术 用于接合铜发卡的方法以及定子 (Method for joining copper hairpins and stator ) 是由 O·博克斯罗克 T·黑塞 于 2020-02-11 设计创作，主要内容包括：本发明涉及一种用于接合铜发卡(10、12)的方法,包括：提供所述铜发卡(10、12)的至少两个待彼此接合的末端,以及以波长小于1000nm的加工射束(2)通过激光射束焊接来接合待接合的铜发卡(10、12)。(The invention relates to a method for joining copper haircards (10, 12), comprising: -providing at least two ends of the copper hairpins (10, 12) to be joined to each other, and-joining the copper hairpins (10, 12) to be joined by laser beam welding with a machining beam (2) having a wavelength of less than 1000 nm.)

1. A method for joining copper haircards (10, 12), comprising:

providing at least two ends of the copper hair card (10, 12) to be joined to each other, and

the copper haircards (10, 12) to be joined are joined by laser beam welding with a machining beam (2) having a wavelength of less than 1000 nm.

2. Method according to claim 1, characterized in that a green machining beam, in particular a laser beam having a wavelength of 500nm to 550nm, preferably having a wavelength of 510nm to 520nm, or a blue machining beam, in particular a laser beam having a wavelength of 425nm to 475nm, preferably having a wavelength of 440nm to 450nm, is used as the machining beam (2).

3. Method according to claim 1 or 2, characterized in that the copper hairpins (10, 12) to be joined are welded to each other by means of heat conduction welding, and the intensity of the machining beam is preferably selected such that deep-melt welding and/or the formation of vapour capillaries are substantially avoided.

4. Method according to any one of the preceding claims, characterized in that the machining beam (2) loads the end faces (114, 124) of the hairpins (10, 12) to be joined and preferably radiates in the longitudinal direction (Z) of the hairpins (10, 12).

5. Method according to one of the preceding claims, characterized in that the machining beam (2) is shaped such that it accommodates the cross-sectional geometry of the hairpin (10, 12) on the end side (114, 124) of the hairpin and, preferably, the cross-section of the machining beam (2) is completely loaded by the end side (114, 124) of the hairpin (10, 12).

6. Method according to one of the preceding claims, characterized in that the machining beam (2) is shaped such that it loads the cross-sectional geometry of the hair clip (10, 12) on the end side (114, 124) of the hair clip with at least two different intensities, preferably with a first intensity in a first region (22) of the end side (114, 124) and with a second intensity in a second region (20) of the end side (124).

7. The method according to any one of the preceding claims, characterized in that the machining beam (2) is configured such that it has a different intensity in its center (20) than in its edge regions (22).

8. The method according to claim 7, characterized in that the processing beam (2) is provided by a core fiber and a ring fiber, into which different intensities and/or different wavelengths are coupled.

9. A method according to any one of the preceding claims, characterized in that the intensity of the machining beam (2) is chosen such that no or substantially no gasification of the material of the copper hairpin (10, 12) takes place.

10. Method according to any of the preceding claims, characterized in that a hair clip (10, 12) is provided having a substantially rectangular cross-sectional profile with a width (X) and a depth (Y), wherein a width (X) of 1mm to 10mm and a depth (Y) of 1mm to 10mm are preferably provided, preferably with a width and/or depth of 0.5mm to 1.5mm, or preferably with a width and/or depth of 1.5mm to 6mm, or preferably with a width and/or depth of 6mm to 10 mm.

11. Method according to any of the preceding claims, characterized in that a hair card (30, 32) is provided with a coating (304, 324) for mechanical and/or chemical protection and/or for electrical insulation, wherein the coating is preferably provided in the form of a coating made of PAI (polyamideimide), PEEK (polyetheretherketone), PEI (polyesterimide) or PI (polyimide, e.g. Kapton).

12. Stator for an electric motor, having stator windings constructed from copper hairpins (10, 12) joined to each other, characterized in that the hairpins (10, 12) are joined using the method of any one of the preceding claims.

Technical Field

The invention relates to a method for joining copper hairpins, in particular for joining copper hairpins provided for constructing stator windings of a stator of an electric motor.

Background

In order to construct a stator in an electric motor, it is known to provide a stator cage made of insulating material into which a so-called hairpin made of electrically conductive material, preferably copper, is pushed, inserted or shot, for example by means of compressed air. The hair clips can be of clip-like or linear design, for example, and are present in the stator cage parallel to one another and substantially in the axial direction of the stator or of the electric motor after their introduction into the stator cage. However, the haircards may not be oriented parallel to each other.

A plurality of such hairpins are inserted into the stator cage around its circumference, said hairpins initially not having a mechanical and electrical connection to one another during assembly or production.

The respective free ends of the hair clips are preferably joined to one another in pairs, for example by welding or soldering, after their insertion into the stator cage and after possible reshaping and/or shortening and possible pretreatment, for example paint stripping, for the purpose of producing a complete stator winding. By means of the joining, a mechanical and electrically conductive connection is established between the ends of the respective pairs of hair clips, so that the hair clips, which were initially present in the individual form after insertion, are now connected. However, it is also possible for more than two hair clips to be joined to one another by means of a machining process. By engaging the hairpins, consecutive stator windings can be constructed which are mechanically and electrically connected to each other.

The use of a hairpin instead of a conventional wire winding can, for example, provide advantages in the case of the production of a corresponding stator, since the hairpin can easily be shot or pushed straight into the stator cage. It is also possible to insert several or all hair clips simultaneously, so that a lengthy winding process is dispensed with.

The hairpins used also generally have a substantially square or rectangular cross section, so that, in the case of a correspondingly close side-by-side arrangement of the hairpins in the stator cage, the fill factor of the conductive material, for example copper, filled with the hairpins can be significantly improved in comparison with conventional stator windings consisting of metal wires having a round cross section. Accordingly, the efficiency of the electric motor can be improved on the basis of an increased fill factor and/or the material consumption for the construction of the stator winding can be reduced.

Regardless of the actual cross-sectional geometry, the hairpin generally has at least a much larger cross-sectional area than the wire configured for winding. Thereby, an increased current flow with respect to the wire is achieved. The increase in the operating efficiency of the electric motor that can be achieved in this way is advantageous, in particular in the case of electric motors for motor vehicles, since these very high power requirements must be met.

However, due to the stresses caused by the dimensions and geometry, it is not possible to construct conventional windings with copper hairpins having a larger cross-sectional area and, for example, a rectangular or square cross-section, so that the copper hairpins can only be inserted into the stator cage in the described linear-like configuration.

Before the ends of the hair clip are joined to produce a coherent stator winding, the coating applied to the hair clip is usually removed in the region of the ends that are to be joined. This removal of the coating can be effected, for example, mechanically, chemically or physically, for example by means of a laser.

Before the hair clips are joined, they can also be geometrically arranged and oriented for joining, for example by clipping, reshaping and merging pairs, wherein merging can be achieved, for example, by mechanical clamping of the ends of the hair clips to be joined.

After the preparation has been completed, the respective ends of the hair clips to be joined to one another are then actually joined to one another, for example by laser beam welding with a Near Infrared (NIR), for example a processing beam having a wavelength of 1030 nm. Known laser beam welding of hairpins occurs as a deep melt weld with the formation of vapor capillaries.

In the case of copper hairpins welded by known methods using a machining beam with a wavelength of 1030nm, the absorption of the energy of the machining beam in the material of the hairpins may be irregular due to the different surface properties of the individual hairpins, so that the introduced energy and the volume of the molten material fluctuate accordingly. Accordingly, an irregular joining result may be generated in the joining process of the plurality of hairpin pairs that are sequentially performed. In other words, an unstable process is involved.

Furthermore, copper absorbs relatively poorly energy at wavelengths near 1030nm because copper is highly reflective at these wavelengths. It is therefore necessary to use deep-fusion welding with steam capillary, since, despite the disadvantages associated with laser beam welding of copper with steam capillary, such as the formation of splashes and slag and the formation of process holes in the solidified melt, the energy absorption can be increased significantly by the steam capillary.

Disclosure of Invention

Starting from the known prior art, the object of the present invention is to provide a method for joining copper haircards (a plurality of copper haircards), which leads to a more uniform joining result.

This object is achieved by a method for joining copper hairpins having the features of claim 1. Advantageous embodiments emerge from the dependent claims, the description and the enclosed drawings,

accordingly, a method for joining copper hair card(s) is proposed, the method comprising: providing at least two ends of a copper hairpin to be joined to one another, and joining the copper hairpins to be joined by laser beam welding with a machining beam having a wavelength of less than 1000 nm.

By using a processing beam with a wavelength of less than 1000nm, the absorption of the processing beam in the hairpin copper material is significantly increased compared to the processing beams used hitherto. In this way, the energy input into the copper hairpins to be joined to one another can be improved, so that correspondingly also the absorption fluctuations due to the different surface properties are small.

In this way, a more uniform absorption of the energy of the processing beam in the copper card can be achieved. In this way, the method for joining copper hairpins can be improved and more stable, so that finally a more consistent joining result can be achieved.

Preferably, for laser beam welding of the copper hairpins to be joined, a green processing beam is used, for example a laser beam having a wavelength of 500nm to 550nm, particularly preferably 510nm to 520nm, or a blue processing beam, for example a laser beam having a wavelength of 425nm to 475nm, particularly preferably 440nm to 450 nm.

Since the absorption in the copper material is improved in these wavelength ranges, the joining process can accordingly be performed in a more controlled manner, so that more consistent joining results can be achieved.

Whether the welding process is a thermal conduction process or a deep-fusion welding process depends decisively on the energy density or the intensity of the machining beam with which the copper hairpins to be joined to one another are loaded. Ideally, exceeding a so-called intensity threshold, from which the heat conduction process is transferred into the deep-fusion welding process, should be avoided.

However, it is also conceivable to use high processing energies, as long as the processing energies are distributed over a large area, for example in the case of hairpins having a diameter which exceeds the average horizontal size. The resulting energy density or intensity of the machining beam is then preferably set again on account of the large machining surface, so that an intensity threshold is not exceeded, from which the heat conduction process is transferred into the deep-fusion welding process.

The laser welding of copper hairpins with a machining beam in the proposed wavelength range is preferably carried out essentially by means of thermal conduction welding. The process of laser welding is therefore more stable and controllable, since fluctuations in the energy input into the material to be melted, which occur when the vapor capillary is formed, can be reduced or avoided.

By using the described processing beam wavelength, a welding method can be correspondingly carried out due to the increased absorption of energy by the copper material, which does not require steam capillary at all or only requires the formation of a small steam capillary. The vapor capillaries that can be formed then have a small aspect ratio (depth/width). Accordingly, in the proposed welding process, heat conduction and heat conduction welding dominates, and deep-melt welding with steam capillary does not occur or at least does not dominate the welding process.

It is also easier to maintain the power of the machining beam at a level that is favorable for heat transfer welding, as the machining beam is more absorbed into the material of the copper card. In other words, a high machining energy density or strength of the machining beam, which can lead to a penetration welding, can be dispensed with. Thus, small fluctuations in the energy input into the copper hairpins to be joined by means of the machining beam also do not lead to an interruption of the welding process, so that the welding process as a whole proceeds more stably.

In this way, the process of forming the vapor capillary during the soldering process can also be omitted or the use thereof can be significantly reduced, since the absorption of the processing beam in the copper material of the copper card increases significantly at the proposed wavelength.

The machining beam is preferably introduced here onto the end faces of the hair clips to be joined, i.e. in particular in the longitudinal direction of the hair clips to be joined to one another. Accordingly, the heat conduction takes place along the longitudinal direction or along the extension of the respective clip.

The machining beam is preferably adapted to the geometry of the hair clips to be joined to one another. Preferably, the end faces of the hair clips to be joined to one another are completely loaded with the machining beam.

Accordingly, the entire end face of the hairpin is loaded with the machining beam, so that heat conduction and thus melting can only take place in the remaining dimension, i.e. in the longitudinal direction of the copper hairpin.

In a preferred alternative, the end faces of the hair clips to be joined to one another can also be loaded only partially for processing the beam. In this case, the central region is not loaded at all by the machining beam, so that the intensity of the machining beam in this central region is equal to 0. Accordingly, the region of the end face to which the machining beam is applied is formed, for example, in the shape of a frame or a ring.

In a further preferred alternative, the end face can also be acted upon by a machining beam having a first intensity in the first region and a second intensity in the second region. Alternatively or additionally, the end face can also be acted upon by different wavelengths of the machining beam in the first region and the second region. In other words, the end face can be loaded with a higher strength in a first region of the ring or frame shape and with a lower strength in a central second region, for example.

This can be achieved, for example, by machining the beam-loading end face by means of a so-called "2 in 1" fiber, which has a core fiber and a ring fiber into which different laser powers can be coupled. In this way, the power in the core fiber can be reduced, so that the machining beam has a lower intensity in the center than in the edge region. If the power in the core fiber is equal to 0 and only the laser power is coupled into the ring fiber, the end face of the hairpin is not loaded at all with energy in the middle and the intensity of the machining beam in the middle is accordingly equal to 0.

The aforementioned plane of the end face loaded with different intensities of the machining beam takes into account in particular the following situations: the thermal diffusion takes place through the outer walls of the hair clip in the edge regions of the cross-section of the machining beam incident on the hair clip, which thermal diffusion is absent in the central region, since this central region is surrounded by the edge regions. Accordingly, a substantially uniform heating of the hairpin cross-section is still achieved due to the non-uniform input of machining energy by the machining beam.

The common points of the above methods are: machining energy is introduced into the end faces of the copper hairpins to be joined to one another. Accordingly, a substantially one-dimensional heat conduction takes place, which propagates in the form of a burning candle substantially in the direction along which the material for joining the hairpins to be joined to one another melts. In this way, a controlled melting of the material of the copper hairpin, which is accordingly loaded with the machining beam, can be carried out, so that good control of the method is achievable.

This good control is especially the case: the material (for example, in the present case, the material of a copper hairpin) has a high thermal conductivity, and the geometry of the components to be joined to one another can accordingly lead to a one-dimensional heat conduction, as can be the case, for example, in the case of a hairpin geometry.

Thus, the weld penetration depth is also not limited by the available strength of the machining beam, but rather by the surface tension of the liquid bead. Accordingly, melting can continue and thereby accumulate the liquid volume of the bead until the bead flows away. However, it is preferred that the welding process is interrupted before such a flow of the bead.

Accordingly, a very robust method is provided, wherein constant welding results are achieved for all successively joined hair card pairs due to the high absorption of the machining beam by the material of the copper hair card.

The high degree of absorption ultimately leads to: there are only small fluctuations in the energy introduced, since fluctuations in the surface properties lead only to relatively small fluctuations in the energy introduced into the material of the hairpin. Thus, the fluctuation of the surface characteristics does not cause drastic changes in the welding procedure, so that accordingly more stable welding results are achieved. In addition, since the formation of vapor capillaries is avoided, spatter is hardly generated when the hairpins are welded and the welding results in less tendency to form process holes.

Furthermore, because of the use of the wavelength range described above, the intensity of the machining beam can be set such that no or only very little vaporization occurs. This is possible because the absorption of the processing beam in the copper material of the copper card is high.

Preferably, a hair clip is provided having a substantially rectangular cross-sectional profile with a width and a depth, wherein a width of 1mm to 10mm and a depth of 1mm to 10mm are preferably provided. Preferably, small hair clips can have a width and/or depth of 0.5mm to 1.5mm, medium size hair clips can preferably have a width and/or depth of 1.5mm to 6mm, and large hair clips can have a width and/or depth of 6mm to 10 mm.

Preferably, a hair card is provided with a coating for mechanical and/or chemical protection and/or for electrical insulation, wherein the coating is preferably provided in the form of a coating made of PAI (Poliamid-Imid), peek (polyether Ether keton), PEI (Polyester-Imid) or PI (Polyimid, e.g. Kapton).

The above-mentioned object is also achieved by a stator for an electric motor having the features of claim 12.

Accordingly, a stator for an electric motor is proposed, having stator windings constructed from copper hairpins joined to one another. According to the invention, the hair clips are joined using the method described above.

The stator windings are therefore joined essentially by heat-conducting welding, so that greater homogeneity between the individual joining points and fewer process holes formed in the joining points can be achieved.

Drawings

Further preferred embodiments of the invention are set forth in more detail in the following description of the figures. Shown here are:

fig. 1 shows a schematic side view of two copper hair clips to be joined to one another, which are loaded for processing a beam;

fig. 2 shows a schematic top view of the end sides of two copper hairpins of fig. 1 to be joined to one another and of a machining beam;

fig. 3 shows a further schematic top view of two copper hairpins to be joined to one another with a further machining beam having two different intensity regions.

Detailed Description

Hereinafter, preferred embodiments are described with reference to the accompanying drawings. Here, the same, similar or functionally identical elements are provided with the same reference numerals in different drawings, and repeated description of these elements is partially omitted to avoid redundancy.

In fig. 1, the ends of the two hair clips 10, 12 are shown schematically, respectively, which ends have been in the engaged position. For this purpose, in the illustrated construction, the two ends of the hair clips 10, 12 are already cut short and lie against one another in such a way that joining can be achieved by means of laser beam welding.

The end faces 114, 124 of the ends of the hair clips 10, 12 point upwards in fig. 1 toward the machining beam 2.

In order to be able to join the ends of the hair clips 10, 12 by means of laser welding, the hair clips 10, 12 with their ends to be joined respectively lie against one another at least in the common plane 3, wherein the gap between the two ends of the hair clips 10, 12 should be kept as small as possible and preferably no gap should be present. The contact surface between the two ends of the hair clips 10, 12, which lies in the common plane 3, is therefore as large as possible.

Furthermore, the lateral offset of the two ends of the hair clips 10, 12 with respect to the common plane 3 is preferably kept small or is preferably avoided. Furthermore, the height offset of the respective end faces 114, 124 with respect to the two ends of the hair clips 10, 12 is preferably also kept very small or is preferably avoided, and the angular position between the ends of the two hair clips 10, 12 is also preferably kept particularly small or is preferably avoided.

In order to achieve the above-mentioned preferred orientation of the end faces 114, 124 in particular before the actual joining of the two ends of the hair clips 10, 12 and also to be able to maintain this preferred orientation during the joining in this way, the ends of the hair clips 10, 12 are brought together, for example using a mechanical clamp.

The hair clips 10, 12 each have a mechanically and chemically protective and electrically insulating coating 110, 120, which can be provided, for example, in the form of a plastic coating. In the preparation regions 112, 122, which comprise the ends of the hair clips 10, 12 to be joined, the respective coating is removed from the hair clips 10, 12, so that only bare copper material remains in this preparation region and no further coating.

Thus, in the common plane 3, the bare copper material of the two hair clips 10, 12 also lies against one another by providing the preparation areas 112, 122 of the ends of the hair clips 10, 12. Also in this region, the joining by laser beam welding is carried out such that the material melted for welding is present in a contamination-free manner.

The coating 110, 120 of the ends of the hair clips 10, 12 is removed in order to avoid impurities being introduced into the melt during the welding process, which could lead, for example, to an undeterminable strength of the re-solidified material at the joining site and/or defects in the structure of the re-solidified material and/or fluctuations in the electrical conductivity of the re-solidified material. Furthermore, the removal of the coatings 110, 120 prevents toxic fumes from being generated during laser beam welding.

The preparation regions 112, 122 are oriented relative to one another in such a way that the joining of the two copper hairpins 10, 12 can be reliably achieved by laser beam welding.

The clearing or removal of the coating 110, 120 of the hair clips 10, 12 in the preparation regions 112, 122 can take place, for example, by laser machining or by known mechanical or chemical cleaning processes in order to prepare the hair clips 10, 12 for the actual joining.

The process of preparing, orienting, reshaping and merging the two ends of the copper hair card 10, 12 is known in principle and will not be described in detail here.

Fig. 2 shows a top view of two ready-prepared hair clips 10, 12 which are oriented relative to one another and which are to be joined to one another.

As is clear from this top view, the hair clips 10, 12 each have a substantially rectangular cross-sectional profile having a width X and a depth Y, respectively. This cross-sectional contour of the hair clips 10, 12 also corresponds to the contour of the end faces 114, 124 of the hair clips 10, 12, which is then effectively loaded by the machining beam 3. In the embodiment shown, a common plane 3 is formed along the depth extension Y (i.e. perpendicular to the width X), at which the two ends of the hair cards 10, 12 abut against each other.

Typical dimensions of the hair clips 10, 12 are for example a width X of 1mm to 10mm and a depth of 1mm to 10 mm. Preferably, small hair cards can have a width and/or depth of 0.5mm to 1.5mm, medium size hair cards can preferably have a width and/or depth of 1.5mm to 6mm, and large hair cards can have a width and/or depth of 6mm to 10 mm. The specific sizing of the copper haircards 10, 12 depends on the respective application.

The basic material of the copper haircards 10, 12 is, for example, copper, for example oxygen-free copper for electrical applications (ETP-Electrolytic-gauge-Pitch).

The coating 110, 120 of the hair clip can be present, for example, in the form of a coating made of PAI (polyamide imide), PEEK (polyether ether ketone), PEI (polyester imide) or PI (polyimide, for example polyimide tape) in order to protect the basic material of the copper hair clip 10, 12 mechanically and chemically and to provide electrical insulation.

The ends of the hair clips 10, 12 provided for forming the stator winding of the stator of the electric motor accordingly also have such a rectangular cross-sectional profile or possibly a square cross-sectional profile, which accordingly achieves a surface contact of the ends of the hair clips 10, 12 to be joined in the common plane 3.

The joining of the copper hairpins 10, 12 can now be carried out by means of a machining beam 2, which is schematically illustrated in fig. 1 and 2.

As can be seen, for example, in fig. 2, the machining beam 2 is preferably shaped in such a way that it carries the entire end face of the ends of the hair clips 10, 12 to be joined. The entire end face is formed by the end faces 114, 124 of the respective ends of the copper hair clips 10, 12, which are respectively directed upward in fig. 1 and are shown in a top view in fig. 2.

In a preferred alternative, which is shown further below in relation to fig. 3, the end faces 114, 124 of the hairpins 10, 12 to be joined to one another can also be loaded only partially with machining beams.

The machining beam 2 is a laser beam, by means of which the joining of the two hair clips 10, 12 can be achieved by laser beam welding.

The processing beam 2 used here has a wavelength of less than 1000 nm.

Preferably, in the exemplary embodiment shown in fig. 1 and 2, the machining beam 2 is a green machining beam 2, which is formed by a laser beam having a wavelength of 500nm to 550nm, particularly preferably having a wavelength of 510nm to 520 nm. Alternatively, the machining beam 2 is a blue machining beam 2, which is formed by a laser beam having a wavelength of 425nm to 475nm, particularly preferably 440nm to 450 nm.

By means of the selected wavelength range of the machining beam 2, it is achieved that the energy of the machining beam 2 is well absorbed by the cards 10, 12 and in particular by their base material in the form of a copper material. Thus, laser energy and thus thermal energy can be efficiently input into the cards 10, 12, enabling laser beam welding to be achieved by thermal conduction welding. The formation of steam capillaries can be dispensed with, since the absorption of the energy of the machining beam 2 by the copper material is increased.

Whether the welding process is a thermal conduction process or a deep-fusion welding process depends decisively on the energy density or the intensity of the machining beam 2, by means of which the copper hairpins 10, 12 to be joined to one another are loaded. Ideally, exceeding a so-called strength threshold, from which the heat conduction process transitions into the penetration welding process, should be avoided.

However, it is also conceivable to use high processing energies, as long as the processing energy is distributed over a large area, for example in the case of hairpins having a diameter or end face 114, 124 which exceeds the average horizontal size. The resulting energy density or intensity of the machining beam is then preferably set again on account of the large machining surface, so that an intensity threshold is not exceeded, from which the heat conduction process is transferred into the deep-fusion welding process.

If the processing beam 2 loads substantially the entire end faces 114, 124 of the hair clips 10, 12 to be joined to one another with laser energy, the heat conduction in the hair clips 10, 12 takes place from the end faces 114, 124 in the longitudinal direction, which is indicated by the longitudinal direction Z in fig. 1. Accordingly, the heat conduction in the hair clips 10, 12 takes place substantially one-dimensionally, i.e. along the longitudinal direction Z, which is also the heat conduction direction.

Preferably, the machining beam 2 is oriented such that it acts on the end faces 114, 124 of the hair clips 10, 12, respectively, as a machining beam. At the same time, the processing beam 2 is preferably also oriented in such a way that it extends essentially in the longitudinal direction Z of the hair clips 10, 12. Accordingly, if a bead of molten material moves in the direction of the heat propagation, i.e. the longitudinal direction Z of the hair clips 10, 12, in the case of laser beam welding of the hair clips 10, 12, the bead remains in the region of influence of the processing beam 2.

The orientation of the cross section of the machining beam 2 is preferably also oriented as a function of the orientation of the end faces 114, 124 of the ends of the hair pins 10, 12 and in particular as a function of the size and the rotational orientation relative to the axis of the machining beam 2. The dimensioning and rotational orientation of the machining beam 2 is known in principle and will therefore not be discussed further here.

In fig. 3, an alternative configuration of the machining beam 2 is shown, wherein the machining beam 2 is divided and the intensity applied to the end faces 114, 124 of the hair pins 10, 12 is different in the central region 20 than in the edge regions 22 surrounding the central region 20.

In other words, the central region 20 is not loaded with the intensity of the machining beam 2 at all, for example, so that the intensity of the machining beam 2 in the central region 20 is equal to 0. Accordingly, the edge region 22 of the end faces 114, 124, which is loaded with the machining beam 2, is formed, for example, in a frame or in a ring.

In a further preferred alternative, the end faces 114, 124 can also be loaded with a machining beam 2 which has a first intensity in the first region 22 and a second intensity in the second region 20. In the first region 22 and the second region 20, the end faces 114, 124 can alternatively or additionally also be acted upon with different wavelengths of the machining beam 2.

In other words, the end faces 114, 124 can be loaded with a higher strength in the first region 22, which is ring-shaped or frame-shaped, and with a lower strength in the second region 20, which is located in the central region, for example.

This can be achieved, for example, by loading the end faces 114, 124 with the machining beam 2, for example by means of a so-called "2 in 1" fiber, which has a core fiber and a ring fiber into which different laser powers can be coupled. In this way, the power in the core fiber can be reduced, so that the machining beam has a lower intensity in the center than in the edge region. If the power in the core fiber is equal to 0 and the laser power is coupled only into the ring fiber, the end faces 114, 124 of the hairpins 10, 12 are not loaded with energy at all in the middle and the intensity of the machining beam 2 is accordingly equal to 0 in the middle.

The aforementioned loading of the planes of the end faces 114, 124 with different intensities of the machining beam 2 takes into account, in particular, the following: in the edge regions of the machining beam 2, which are incident on the edge regions of the cross section of the hairpins 10, 12, thermal diffusion takes place via the outer walls of the hairpins, whereas in the central region this thermal diffusion is absent, since this central region is surrounded by the edge regions. Accordingly, a substantially uniform heating of the cross-section of the hair clips 10, 12 is still achieved due to the non-uniform input of the machining energy by the machining beam 2.

Since the machining beam 2 is incident on the end faces 114, 124 of the hair pins 10, 12 and is oriented in the longitudinal direction Z of the hair pins 10, 12, a one-dimensional thermal conduction and thus also an extension of the thermal conduction in the direction of the soldering-in depth occurs in principle. Thus, the possibility also arises of an infinite weld-in depth in the hair clips 10, 12, which is theoretically limited only by the extent of the hair clips 10, 12 in the longitudinal direction Z.

In practice, however, the aim is to achieve a clearly delimited penetration depth which produces a bead with no tendency to flow out, in order to avoid uncontrolled distribution of the molten material. In other words, the weld penetration depth is limited by the surface tension of the melt, since it is not desirable for the molten material of the bead to run off.

Furthermore, in this way, a mechanically and electrically reliable connection of the two hairpins 10, 12 can be established, in order to achieve a mechanically and electrically reliable joining of the hairpins 10, 12 in this way and thus to provide a reliable construction of the stator windings of the stator of the electric motor.

All individual features presented in the embodiments can be combined with one another and/or substituted for one another as applicable without departing from the scope of the invention.

List of reference numerals

10 copper hairpin

12 copper hairpin

110 coating

112 preparation area

114 end face

120 coating

122 preparation area

124 end face

2 machining beam

20 central region

22 edge region

3 common plane

Width of X-shaped hair clip

Depth of Y hair clip

Lengthwise direction of Z-hair card