WELDING METHOD AND LASER DEVICE

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2022-032378 filed on Mar. 3, 2022, the contents of which are incorporated herein by reference.

TECHNICAL FIELD

The present disclosure relates to a welding method and a laser device for performing metal welding using laser light.

BACKGROUND

As one of techniques for metal welding, laser welding using laser light is used. As compared with other welding techniques, laser welding allows a workpiece to be welded by a condensing lens with highly compacted energy, and is suitable for fine welding with high welding quality.

In recent years, laser welding has been used to manufacture a stator for a motor to be incorporated into a hybrid vehicle or an electric vehicle. The stator includes a stator core and a plurality of segment coils mounted in slots of the stator core, and end portions of the corresponding segment coils are joined to each other by laser welding. Usually, each segment coil is not a round wire but a flat conductor wire. Accordingly, it is possible to eliminate a gap formed by a round wire and increase a density of the joint portion, thereby implementing low fuel consumption and miniaturization. Since a welding surface is as fine as several millimeters square meters, laser welding is suitable.

JP2021-093832A discloses a laser welding technique for a stator coil. Here, corresponding flat conductors are arranged with a gap therebetween, and end surfaces are laser-melted. At this time, a melted and solidified portion in which the melted flat conductors are solidified enters below the end surfaces so as to dent the end surfaces. That is, it is considered that in the welding method in the related art, a fact that the molten pool expands onto a convex lens and the molten pool becomes deep is one factor of spattering, and in order to prevent this in this technique, the molten flat conductor during welding sequentially flows into the gap, whereby a molten pool at an irradiation point irradiated with the laser light is formed shallowly (see paragraph 0045 of JP2021-093832A).

SUMMARY

According to the above technique, spattering generated during welding can be prevented to keep the welding quality constant. Although it is desired to improve the productivity in the manufacturing process of the stator, there is no finding in the above literature about productivity improvement, such as shortening the processing time.

Therefore, an object of the present disclosure is to provide a welding method and a laser device capable of reducing processing time while maintaining good welding quality in a welding method of performing metal welding by laser welding.

The present disclosure provides a welding method of abutting end portions of a first member and a second member that are arranged facing a laser device against each other and welding the end portions by laser light, wherein an end surface where the first member and the second member are abutted against each other is rotationally irradiated with the laser light at a predetermined rotating diameter, wherein a spot diameter of the laser light is equal to or larger than the rotating diameter, and wherein an irradiation region of the laser light by the rotational irradiation extends over the first member and the second member.

According to the present disclosure, since the spot diameter of the laser light is equal to or larger than the rotating diameter, the central portion of the welding surface is normally irradiated with the laser light. Therefore, it is possible to supply sufficient energy to the central portion of the welding surface, and the welding surface starts melting from the central portion and gradually melts toward the end portion due to thermal conduction. In this way, it is possible to form a clean molten ball without applying excessive heat to the end portions of the welding surface and preventing molten metal from melting from the end portions of the welding surface due to melting from the central portion. By rotational irradiation with the laser light, the concentration of heat is prevented, and a flow in the rotating direction is generated inside the molten pool, thereby further stabilizing the molten pool. As a result, it is possible to prevent generation of spattering and implement high welding quality.

Since the related-art patent literature JP2021-093832A does not have a configuration in which the central portion of the welding surface is normally irradiated with laser light, the welding method according to the present disclosure starts melting at the central portion earlier than the method described in the related-art patent literature JP2021-093832A. Accordingly, the formation of the molten pool is further promoted, and the workpiece to be welded can be quickly melted.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a schematic diagram showing an overall configuration of a laser device 100 according to a first embodiment of the present disclosure;

FIG. 2 is a view showing a configuration of a galvano scanner 8;

FIG. 3A is a perspective view showing a schematic configuration of a stator; FIG. 3B is a diagram showing a segment coil 52; FIG. 3C is a view showing a workpiece W;

FIGS. 4A and 4B are diagrams showing a welding method according to the first embodiment;

FIG. 5 is a schematic diagram showing an overall configuration of a laser device 1 according to a second embodiment of the present disclosure;

FIGS. 6A and 6B are diagrams showing an example (case of r≤d1) of a welding method according to the second embodiment;

FIGS. 7A and 7B are diagrams showing an example (case of r>d1) of the welding method according to the second embodiment;

FIG. 8 is a photograph of the machined workpiece W; and

FIGS. 9A and 9B are views showing welding of segment coils.

DESCRIPTION OF EMBODIMENTS

A welding method according to an aspect of the present disclosure is a welding method of abutting end portions of a first member and a second member that are arranged facing a laser device against each other and welding the end portions by laser light, in which an end surface where the first member and the second member are abutted against each other is rotationally irradiated with the laser light at a predetermined rotating diameter, in which a spot diameter of the laser light is equal to or larger than the rotating diameter, and an irradiation region of the laser light by the rotational irradiation extends over the first member and the second member.

In a welding method according to another aspect of the present embodiment, a wavelength of the laser light is 300 μm to 600 μm.

In the welding method according to another aspect of the present embodiment, the end surface is rectangular, and r≤d1<a when a length of a short side of a rectangle forming the end surface is defined as “a”, a spot diameter of the laser light is defined as “d1”, and the rotating diameter is defined as “r”.

In the welding method according to another aspect of the present embodiment, a spot area (condensing area) of the laser light is 1% to 30% of a total area of the end surface.

In the welding method according to another aspect of the present embodiment, an output power of the laser light is 500 W to 2 kW.

In the welding method according to another aspect of the present embodiment, energy intensity distribution of the laser light on the end surface is highest at a substantially central portion of the irradiation region, is weak at a region other than the substantially central portion of the irradiation region, and is zero outside the irradiation region.

In the welding method according to another aspect of the present embodiment, the end surface is rotationally irradiated with second laser light having a wavelength different from that of the laser light, and a spot diameter of the second laser light is smaller than the spot diameter of the laser light.

In the welding method according to another aspect of the present embodiment, an optical axis of the laser light coincides with an optical axis of the second laser light.

In the welding method according to another aspect of the present embodiment, a wavelength of the second laser light is 780 nm to 1,100 nm.

In the welding method according to another aspect of the present embodiment, the spot diameter of the second laser light is less than 1/10 of the spot diameter of the laser light.

In the welding method according to another aspect of the present embodiment, the spot diameter of the second laser light is 10 μm to 100 μm.

In the welding method according to another aspect of the present embodiment, the laser light and the second laser light are rotated at a rotating speed of 100 mm/s to 1,000 mm/s.

In the welding method according to another aspect of the present embodiment, irradiation time with the laser light and the second laser light is 50 msec or longer.

In the welding method according to another aspect of the present embodiment, each of the first member and the second member is a flat conductor having a rectangular cross section constituting a stator coil, and a molten ball is formed on the end surface by abutting end portions of two flat conductors arranged facing the laser device against each other and welding the end portions with the laser light and the second laser light.

In the welding method according to another aspect of the present embodiment, simultaneously with or before irradiation with the laser light and the second laser light, nitrogen is blown onto the end surface at a flow rate of 5 L/min to 100 L/min and at an inclination angle of 0° to 90° with respect to the end surface until and even after the radiation ends.

A welding method according to an aspect of the present disclosure is a welding method of abutting end portions of a first member and a second member that are arranged facing a laser device against each other and welding the end portions by laser light, in which the laser light includes first laser light and second laser light having different wavelengths, an end surface is irradiated with the first laser light and the second laser light in an annular shape by rotationally irradiating a substantial center of the end surface with the laser light at a predetermined rotating diameter, and a spot diameter of the second laser light is smaller than a spot diameter of the laser light.

A laser device according to an aspect of the present disclosure is a laser device of abutting end portions of a first member and a second member against each other and welding the end portions, the laser device including: an oscillator configured to oscillate laser light; and a galvano scanner configured to rotationally irradiate a substantial center of the end surface with the laser light at a predetermined rotating diameter, in which a spot diameter of the laser light is equal to or larger than the rotating diameter, and an irradiation region of the laser light by the rotational irradiation extends over the first member and the second member.

A laser device according to an aspect of the present disclosure is a laser device of abutting end portions of a first member and a second member against each other and welding the end portions, the laser device including: a first oscillator configured to oscillate first laser light; a second oscillator configured to oscillate second laser light having a wavelength different from that of the first laser light; a combiner configured to superimpose the first laser light and the second laser light on the same optical axis; and a galvano scanner configured to rotationally irradiate a substantial center of the end surface with the first laser light and the second laser light at a predetermined rotating diameter, in which a spot diameter of the first laser light is equal to or larger than the rotating diameter, and a spot diameter of the second laser light is smaller than the spot diameter of the first laser light.

A laser device according to an aspect of the present disclosure is a laser device of abutting end portions of a first member and a second member against each other and welding the end portions, the laser device including: a first oscillator configured to oscillate first laser light; a second oscillator configured to oscillate second laser light having a wavelength different from that of the first laser light; and one or more galvano scanners configured to rotationally irradiate a substantial center of the end surface with the first laser light and the second laser light at a predetermined rotating diameter, in which the end surface is irradiated with the first laser light and the second laser light in an annular shape, and a spot diameter of the second laser light is smaller than a spot diameter of the first laser light.

Here, a laser device 100 according to a first embodiment of the present disclosure will be described. The laser device 100 is a device that performs butt welding on a workpiece formed of a material having a high thermal conductivity, and performs thermal conduction welding by irradiation with a laser such that energy distribution of the laser on a welding surface having a rectangular shape is highest at a central portion and is zero at a peripheral edge.

FIG. 1 is a diagram showing a schematic configuration of the laser device 100. As shown in the figure, the laser device 100 includes a first oscillator 2 that oscillates first laser light L1, a transmission fiber 21 which is an optical fiber that transmits the first laser light L1, a collimating lens 22 that converts the first laser light L1 into parallel light, a condensing lens 6 that reduces a spot diameter of the first laser light L1, a protective glass 7 that protects the condensing lens 6, a galvano scanner 8 that two-dimensionally displaces an irradiation position of the first laser light L1 with respect to the workpiece W, and shield nozzles 9a and 9b that supply a shielding gas to the workpiece W. The laser device 100 may include other optical systems, optical fibers, and the like in addition to the above components.

In the present embodiment, a blue semi-conductor laser coupled to a multimode fiber is used as the first laser light L1. The first laser light L1 may have a wavelength of 300 nm to 600 nm, and a green laser may be used instead of the blue laser. An output power of the first laser light L1 is preferably 500 W to 2 kW.

Next, the galvano scanner 8 will be described. FIG. 2 is a diagram schematically showing a configuration of the galvano scanner 8. As shown in the figure, the galvano scanner 8 includes an X-axis galvano mirror 81, an X-axis galvano motor 82 for rotating the X-axis galvano mirror 81, a Y-axis galvano mirror 83, and a Y-axis galvano motor 84 for rotating the Y-axis galvano mirror 83. That is, the galvano scanner 8 has a function of deflecting the first laser light L1 in any two-dimensional direction. A stepping motor, a servo motor, or the like can be used as the X-axis galvano motor 42 and the Y-axis galvano motor 44.

The galvano scanner 8 is connected to a control unit (not shown) and drives the motors 82 and 84 based on a control command transmitted from the control unit to two-dimensionally control the irradiation position of the first laser light L1 on the workpiece W. More specifically, the first laser light L1 is controlled to rotate on a two-dimensional plane of the workpiece W.

The workpiece W to be welded will be described with reference to FIGS. 3A to 3C. FIG. 3A is a perspective view showing a schematic configuration of a stator 50 which is a stator of a motor of an electric vehicle or the like. As shown in the figure, the stator 50 includes a substantially cylindrical stator core 51 and a plurality of segment coils 52. Each of the segment coils 52 is an electric wire having a rectangular cross section, that is, a flat conductor. The segment coil 52 is usually made of pure copper, but may be made of a metal material having a high conductivity, such as an alloy containing copper as a main component or an alloy containing copper and aluminum. An end portion of the segment coil 52 protrudes from an upper end portion of the stator core 51, and the laser device 100 performs laser welding on end portions of two segment coils (flat conductors) 52 adjacent to each other in a radial direction of the stator core 51.

First, as shown in FIG. 3B, abutting surfaces 52b of the segment coils (flat conductors) 52 from which an insulating coating is peeled are abutted against each other. At this time, the segment coils 52 may be abutted against each other using a jig (not shown). As shown in FIG. 3C, end surfaces 52a of the two abutted segment coils 52 serve as welding surfaces, that is, the workpiece W according to the present embodiment. Here, a gap of the welding surfaces may cause poor welding. In order to prevent poor welding, it is preferable that the end surfaces 52a of the two segment coils 52 are abutted against each other so as to be flush with each other. The laser device 100 rotationally irradiates, with the first laser light L1, the end surfaces 52a against which two adjacent segment coils 52 abut to weld the two adjacent segment coils 52.

Next, a welding method with the laser device 100 will be described in detail with reference to FIGS. 4A and 4B.

FIG. 4A is a diagram schematically showing an irradiation region of the first laser light L1 on the workpiece W in a state where the galvano scanner 8 is stopped. As described above, the workpiece W has a rectangular shape in which the end portions of the two segment coils 52 abut against each other, and a size thereof is any size. In a case of a segment coil of a normal stator, 2.5 mm≤a≤4.0 mm and about 3.0 mm≤b≤5.0 mm when a length of a short side is defined as “a” and a length of a long side is defined as “b”. Thus, a total area (a×b) of the workpiece W is about 7.5 mm²≤(a×b)≤20.0 mm². In the present embodiment, as an example, a=2.8 mm and b=3.2 mm.

As shown in FIG. 4A, the first laser light L1 is rotated with a rotating diameter “r” with respect to a center 0 of the workpiece W as indicated by an arrow, in which the spot diameter of the first laser light L1 is defined as “d1”. At this time, r<d1≤a. Preferably, r<d1 <a.

The spot diameter d1 may be determined such that a spot area (gray region in FIG. 4A) of the first laser light L1 becomes 1% to 30% of the total area of the workpiece W. Here, as an example, the rotating diameter r is 800 and the spot diameter “d1” is 1,050

When the first laser light L1 is rotated from this state, as shown in FIG. 4B, an irradiation region S (light gray region in FIG. 4B) of the first laser light L1 becomes circular, and the diameter becomes “d1+r”. Here, in order to form a clean molten ball on the workpiece W, it is desirable that a distance “a”′ from an outer periphery of the irradiation region S of the first laser light L1 to an edge portion of the workpiece W is at least 0.2 mm or longer. If the distance “a”′ from the outer periphery of the irradiation region S to the edge portion of the workpiece W is too short, spattering may occur or molten metal may melt and flow.

As shown in FIG. 4B, a circular region “s” (dark gray region in FIG. 4B) having a diameter “d1−r” in the central portion of the workpiece W is always irradiated with the first laser light L1. That is, the energy distribution of the first laser light L1 is the highest in the circular region “s” which is the central portion of the workpiece W, is lower and constant in the other regions than the central portion, and is zero since the outside of the irradiation region S is not irradiated with the first laser light L1.

The laser device 100 rotates the first laser light L1 at a rotating speed of 500 mm/s. The irradiation time with the first laser light L1 is 50 msec or longer.

In this way, since the central portion of the workpiece W is normally irradiated with the first laser light L1 in the laser device 100, the central portion of the workpiece W can be irradiated with the first laser light L1 at a sufficient energy density. Therefore, melting starting at the central portion is fast, and the workpiece W is gradually melted from the central portion toward the end portion due to thermal conduction. Here, although the workpiece W is made of copper having a very high thermal conductivity, since the edge portion of the workpiece W has no heat escape area in the periphery thereof, the molten metal is melt and flows when excessive heat is applied to the edge portion of the workpiece W and a clean molten ball cannot be formed. Therefore, in the laser device 100 according to the present embodiment, the edge portion of the workpiece W is not irradiated with laser light, and the workpiece W is gradually molten from the central portion toward the end portion, thereby forming a clean molten ball.

By rotational irradiation with the first laser light L1, it is possible to supply necessary energy to the workpiece W without using a laser light source having a large spot diameter and a large output.

In the laser device 100, nitrogen, which is a shielding gas, is blown to the welding surface at 5 L/min to 100 L/min simultaneously with or before irradiation with the first laser light L1 until and even after the irradiation ends. More preferably, blowing is performed at 10 L/min to 40 L/min. As shown in FIG. 1, in the present embodiment, nitrogen is blown from the left and right using the two shield nozzles 9a and 9b. An angle of each of the shield nozzles 9a and 9b with respect to the workpiece W is, for example, 30 degrees. A diameter of a tip opening of each of the shield nozzles 9a and 9b (nozzle tip diameter) is preferably about 1 mm to 10 mm. A working distance, which is a distance from the tip opening of each of the shield nozzles 9a and 9b to the workpiece W, is preferably about 5 mm to 15 mm.

By supplying nitrogen to the workpiece W via the shield nozzles 9a and 9b, the laser device 100 performs welding on the workpiece W in a nitrogen atmosphere. Oxidation of the welding surface is prevented by the shielding gas, and accordingly, a decrease in welding strength and generation of porosity caused by oxidation of the welding surface can be prevented. Further, by suitably selecting conditions such as the flow rate of the shielding gas, the nozzle tip diameter, and the working distance, it is possible to prevent the swing of the molten ball and form a clean molten ball. In particular, by blowing nitrogen from the left and right, a laterally symmetric clear molten ball is formed. Accordingly, the welding quality is improved.

Next, a second embodiment of the present disclosure will be described. The second embodiment is a welding method in which the welding process can be performed at a higher speed by irradiation with second laser light L2 in addition to the first laser light L1.

FIG. 5 is a diagram showing a schematic configuration of a laser device 1 according to the second embodiment. As shown in the figure, the laser device 1 includes the first oscillator 2 that oscillates the first laser light L1, a second oscillator 3 that oscillates the second laser light L2, the transmission fiber 21 which is an optical fiber that transmits the first laser light L1, a transmission fiber 31 which is an optical fiber that transmits the second laser light L2, the collimating lens 22 that converts the first laser light L1 into parallel light, a collimating lens 32 that converts the second laser light L2 into parallel light, mirrors 4 and 5 that make optical axes of the first laser light L1 and the second laser light L2 coincide with each other, the condensing lens 6 that reduces a spot diameter of each of the first laser light L1 and the second laser light L2, a protective glass 7 that protects the condensing lens 6, the galvano scanner 8 that displaces irradiation positions of the first laser light L1 and the second laser light L2 with respect to the workpiece W, and the shield nozzles 9a and 9b that supply a shielding gas to the workpiece W.

The laser device 1 may further include other optical systems, optical fibers, and the like in addition to these components.

The first laser light L1 and the second laser light L2 oscillated from the first oscillator 2 and the second oscillator 3 are parallelized by the collimating lenses 22 and 32, respectively. The first laser light L1 and the second laser light L2 that pass through the collimating lenses 22 and 32, respectively, are superimposed on the mirror 4 and the mirror 5, respectively, such that optical axes thereof coincide with each other. Thereafter, the optical axis is changed toward the condensing lens 6, and a diameter of the optical axis is reduced to a predetermined diameter by the condensing lens 6. Then, at the galvano scanner 8, the workpiece W opposed thereto is rotationally irradiated. The mirror 5 is a dichroic mirror that reflects a wavelength of the first laser light L1 and transmits a wavelength of the second laser light L2. In this way, the laser device 1 performs welding by irradiating the workpiece W with the two laser light L1 and L2.

The first laser light L1 is basically the same as that of the first embodiment. That is, an output power of the first laser light L1 is preferably 500 W to 2 kW, and is 600 W as an example in the present embodiment. An output power of the second laser light L2 is preferably 500 W to 2 kW, and is 900 W as an example in the present embodiment.

The wavelength of the first laser light L1 is 300 nm to 600 nm, and the wavelength of the second laser light L2 is 780 nm to 1,100 nm. That is, the first laser light L1 and the second laser light L2 have different wavelengths, and the wavelength of the first laser light L1 is shorter than the wavelength of the second laser light L2. Although as the beam mode, either a multimode or a single mode can be used, in the present embodiment, the first laser light L1 uses the multimode and the second laser light L2 uses the single mode. As will be described later, the second laser light L2 is spot light having a smaller spot diameter than the first laser light L1. Therefore, by using a single-mode fiber laser as the second oscillator 3, it is possible to effectively generate the second laser light L2 having a small beam diameter and a high energy intensity.

Next, the welding method by the laser device 1 will be described in detail with reference to FIGS. 6 and 7. In the first embodiment described above, the spot diameter d1 of the first laser light L1 satisfies r≤d1<a, the spot diameter “d1” is larger than the rotating diameter “r”, and the center of the workpiece W is normally irradiated with the first laser light L1. On the other hand, in the second embodiment, the spot diameter d1 of the first laser light L1 may be larger, smaller, or the same size as the rotating diameter “r”.

FIGS. 6A and 6B show an example of a welding method in a case where the spot diameter “d1” of the first laser light L1 satisfies r<d1 as in the first embodiment. FIGS. 7A and 7B show an example of a welding method in a case where the spot diameter “d1” of the first laser light L1 satisfies r>d1.

First, an example of r<d1 will be described. FIG. 6A is a diagram schematically showing irradiation regions of the first laser light L1 and the second laser light L2 on the workpiece Win a state where the galvano scanner 8 is stopped. The workpiece W is as described in the first embodiment, and in the present embodiment, the size of the workpiece W is, for example, a=2.8 mm and b=3.2 mm.

As shown in FIG. 6A, the first laser light L1 and the second laser light L2 are circular beams having the same optical axis and the spot diameters “d1” and “d2”, respectively. The first laser light L1 and the second laser light L2 are rotated with the rotating diameter r with respect to the center 0 of the workpiece W as indicated by an arrow. Here, as an example, the spot diameter “d1” of the first laser light L1 is 1,050 μm, and the rotating diameter r is 800 μm. The spot diameter d2 of the second laser light L2 is smaller than the spot diameter “d1” of the first laser light L1, and for example, “d2” is equal to or less than 1/10 of “d1”. Here, “d2” is 40μm as an example.

Similarly to the first embodiment, the spot diameter “d1” may be determined such that a spot area (gray region in FIG. 6A) of the first laser light L1 becomes 1% to 30% of a total area of the workpiece W.

When the first laser light L1 and the second laser light L2 are rotated from this state, as shown in FIG. 6B, the irradiation region S (light gray region in FIG. 6B) of the first laser light L1 becomes circular, and the diameter thereof becomes “d1+r”. In order to form a clean molten ball on the workpiece W, it is desirable that the distance “a”′ from an outer periphery of the irradiation region S of the first laser light L1 to an edge portion of the workpiece W is at least 0.2 mm or longer. If the distance “a”′ from the outer periphery of the irradiation region S to the edge portion of the workpiece W is too short, spattering may occur or molten metal may melt and flow.

As shown in FIG. 6B, the circular region “s” (dark gray region in FIG. 6B) having the diameter “d1−r” in a central portion of the workpiece W is always irradiated with the first laser light L1. That is, energy distribution of the first laser light L1 is the highest in the circular region “s” which is the central portion of the workpiece W, is lower and constant in regions other than the central portion, and is zero since the outside of the irradiation region S is not irradiated with the first laser light L1.

In the second embodiment, the irradiation with the second laser light L2 is added, whereby the irradiation region R of the second laser light L2 has an annular shape as shown in FIG. 6B. Here, the workpiece W is additionally irradiated with the second laser light L2 so as to supply energy, that is, heat necessary for melting, and is not intended to form a keyhole in the workpiece W. Therefore, the laser device 1 according to the present embodiment may form a keyhole by irradiation with the second laser light L2 or may not form a keyhole.

In this way, in the case of “r≤d1”, since the central portion of the workpiece W is normally irradiated with the first laser light L1, the central portion of the workpiece W can be irradiated with the first laser light L1 at a sufficient energy density. Therefore, the heat is most accumulated in the central portion, the temperature rises most at a joint surface of the two segment coils 52, and a deep molten pool is formed at the abutting surface 52b. Due to thermal conduction, the workpiece W is gradually melted toward the end portion thereof. That is, the laser device 1 according to the present embodiment performs thermal conduction welding similarly to the laser device 100 according to the first embodiment.

The laser device 1 further irradiates the workpiece W with the second laser light L2 in a state where the thermal absorption rate is increased by irradiation with the first laser light L1. Accordingly, the melting of the workpiece is accelerated, and the speed of the welding process can be increased.

Next, an example of “r>d1” will be described. FIG. 7A is a diagram schematically showing the irradiation regions of the first laser light L1 and the second laser light L2 on the workpiece W in a state where the galvano scanner 8 is stopped. When the first laser light L1 and the second laser light L2 are rotated from this state, as shown in FIG. 7B, the central portion of the workpiece W is not irradiated with the first laser light L1, and the irradiation region S of the first laser light L1 (gray region in FIG. 7B) becomes annular. An outer diameter of the irradiation region S is “d1+r”, and an inner diameter is “r-d1”. It is desirable that the distance “a”′ from the outer periphery of the irradiation region S to the edge portion of the workpiece W is at least 0.2 mm. The irradiation region R of the second laser light L2 has an annular shape as shown in FIG. 7B.

In this way, even in the case where the central portion of the workpiece W is not irradiated with the first laser light L1, by adding the irradiation with the second laser light L2, melting starts from the portion irradiated with the second laser light L2 immediately after the start of the irradiation, but heat propagates to the central portion of the workpiece W, and the energy is most accumulated in the central portion. Therefore, the temperature most rises at the joint surface of the two segment coils 52, and a deep molten pool is formed at the abutting surface 52b. Further, the melting of the workpiece is accelerated by the irradiation with the second laser light L2, and the speed of the welding process can be increased. Since the edge portion of the workpiece W is not irradiated with the laser light, the workpiece W is gradually melted from the central portion toward the end portion of the workpiece W, and a clean molten ball can be formed.

The laser device 1 rotates the first laser light L1 and the second laser light L2 at a rotating speed of 500 mm/s. The irradiation time with the first laser light L1 and the second laser light L2 is 50 msec or longer. Similarly to the first embodiment, the laser device 1 performs welding on the workpiece W in a nitrogen atmosphere while supplying nitrogen to the workpiece W via the shield nozzles 9a and 9b. The flow rate of the shielding gas and the conditions of the nozzle are the same as those in the first embodiment.

The laser device 100 forms a molten pool on the workpiece W by rotationally irradiating the first laser light L1 having a wavelength of 300 nm to 600 nm and a high optical absorptance with respect to copper. The laser device 100 does not irradiate a center of an irradiation surface with strong energy and does not irradiate a peripheral portion of the irradiation surface with laser light. By irradiation with the first laser light L1 with such an energy distribution, it is possible to form a clean molten ball on a workpiece having high thermal conductivity.

When irradiation at a fixed point is temporarily performed without rotationally irradiation with the first laser light L1, a high-output blue laser light source is required, but a high-output blue laser source is still hard to come by and expensive. Further, in a case of irradiation with the first laser light L1 at a fixed point, a large amount of spattering may be generated.

The laser device 1 forms a molten pool on the workpiece W by rotationally irradiating the workpiece W with the first laser light L1 having a wavelength of 300 nm to 600 nm and a high optical absorptance with respect to copper. Then, the second laser light L2 having a small spot diameter and a high energy density is irradiated while being rotated at a high speed in the molten pool to be formed, whereby a locally deep penetration depth in the molten pool is implemented and the formation of the molten pool is promoted.

The laser device 1 and the laser device 100 use the first laser light L1 having a larger spot diameter for welding than a welding device in the related art. The laser device 1 and the laser device 100 can further apply heat to the workpiece W to melt the workpiece W by rotational irradiation with the first laser light L1.

Further, the laser device 1 and the laser device 100 generate a flow in the molten pool by rotational irradiation with the first laser light L1 and the second laser light L2 instead of irradiation at a fixed point. Air bubbles generated from the molten pool that reaches a high temperature are discharged to the outside. Accordingly, the porosity can be reduced. Further, it is possible to prevent heat from being locally concentrated in the molten pool, stabilize the molten pool, and reduce spattering. Since porosity and spattering cause welding defects such as defective joining, the laser device 1, the laser device 100, and the welding method using these devices can prevent the occurrence of welding defects.

FIG. 8 shows a result of welding the segment coils 52 of the stator 50 using the laser device 1 according to the second embodiment. As shown in the figure, it can be seen that a glossy and laterally symmetric clean molten ball is formed.

Further, since in the laser device 1 and the laser device 100, the optical axis of each laser light can be two-dimensionally displaced by the galvano scanner 8, the processing time required for welding the segment coils for the stator in each stage can be shortened as compared with a laser device that does not include the galvano scanner 8.

In a case where the welding of the segment coils is performed by the laser device which does not include a galvano scanner, as shown in FIG. 9A, irradiation positions with the laser light L1 and L2 are first aligned with a workpiece W1, followed by laser irradiation. Next, in order to weld a workpiece W2, the laser device 1 is conveyed by a conveying mechanism (not shown) so that an irradiation nozzle faces the workpiece W2, and irradiation positions of the laser light L1 and L2 are aligned with the workpiece W2, followed by laser irradiation. Similarly, regarding workpieces W3 and W4, it is necessary to repeatedly perform conveyance, positioning, and laser irradiation of the laser device.

On the other hand, when the laser device 1 and the laser device 100 including the galvano scanner 8 are used, as shown in FIG. 9B, the irradiation positions of the laser light L1 and L2 with respect to the workpiece W1 are aligned by the galvano scanner 8, followed by laser irradiation. Next, in order to weld the workpiece W2, the irradiation positions of the laser light L1 and L2 with respect to the workpiece W2 are aligned by the galvano scanner 8, followed by laser irradiation. That is, in the laser device 1 and the laser device 100, the conveyance of the laser device is not necessary by using the galvano scanner 8. Similarly, regarding the workpiece W3 and the workpiece W4, it is not necessary to convey the laser device each time the workpiece is welded, and positioning and laser irradiation can be repeatedly performed.

In this way, in the laser device 1 and the laser device 100, the time required for conveying the laser device is not required, and the processing time can be shortened.

Although the laser device 1 and the laser device 100 have been described above as embodiments of the present disclosure, the present disclosure is not limited to the laser device 1, the laser device 100, and the welding method using the laser device 1 and the laser device 100 described above, and the above embodiments can be modified as follows.

Here, a modification of the above embodiments will be described. The above embodiments and the modification described below can be combined in any way.

(1) In the second embodiment, the laser device 1 superimposes the laser light L1 and L2 having different wavelengths. Here, a refractive index of the light depends on the wavelength of the light, and when a plurality of laser light having different wavelengths are superimposed and pass through a lens or the like, the irradiation position of the first laser light L1 and the irradiation position of the second laser light L2 may be shifted on the workpiece W. In order to prevent this, the laser device 1 may include an f0 lens, or a 3D galvano scanner may be used instead of the galvano scanner 8. Further, other optical systems, optical fibers, and the like may be provided.

(2) In the first embodiment and the second embodiment, the spot diameter “d1” of the first laser light L1 is not limited to 1,050 As described above, the spot diameter d1 can be selected such that the area (spot area, condensing area) of the irradiation region with the first laser light L1 becomes 1% to 30% of the total area of the workpiece W.

Further, in the second embodiment, the spot diameter “d2” of the second laser light L2 is not limited to 40 The spot diameter d2 of the second laser light L2 can be about 10 μm to 100 μm, and is preferably 1/10 or less of the spot diameter “d1” of the first laser light L1.

The spot diameter of each laser light depends on a core diameter of the transmission fiber, a focal length of the collimating lens, and a focal length of the condensing lens, and can be calculated by the following equation: spot diameter=core diameter of transmission fiber ×(focal length of condensing lens/focal length of collimating lens). Therefore, by adjusting these optical systems, it is possible to change the spot diameter of each laser light.

(3) In the first embodiment and the second embodiment, the rotating speed of the first laser light L1 and the second laser light L2 is 500 mm/s, but the rotating speed of the first laser light L1 and the second laser light L2 is not limited thereto, and may be within a range of 100 mm/s to 1,000 mm/s.

(4) In the second embodiment, the first laser light L1 is the multimode and the second laser light L2 is the single mode, but this is an example, and the beam mode of each laser light is not limited.

(5) In the first embodiment and the second embodiment, the shield nozzles 9a and 9b of a side nozzle type are used to avoid interference with an operation of the galvano scanner 8 and to effectively supply nitrogen, but it is needless to say that the shield nozzle is not limited to a shield nozzle of a side nozzle type. The shield nozzle may be any nozzle as long as it can blow nitrogen to the welding surface at an inclination angle of 0° to 90° and weld the welding surface in a nitrogen atmosphere.

(6) In the first embodiment and the second embodiment, the first laser light L1 and the second laser light L2 are focused on the workpiece W (welding surface), but in the present disclosure, the first laser light L1 and the second laser light L2 may be focused at positions within a range of ±2 mm from the welding surface in a vertical direction.

(7) In the first embodiment and the second embodiment, the first laser light L1 and the second laser light L2 are circular beams, but the beam shapes of the first laser light and the second laser light are not limited thereto. For example, an elliptical beam or a rectangular beam may be used. In this case, a longitudinal direction of a rectangular welding surface is preferably a major axis.

(8) In the first embodiment and the second embodiment, the stator coil is described as an example of the workpiece. However, the welding method, the laser device 1, and the laser device 100 are not limited to a case of being used for welding the stator coil.

(9) In the second embodiment, the optical axis of the first laser light L1 and the optical axis of the second laser light L2 are made to coincide with each other, and rotational irradiation is performed by the galvano scanner 8. However, the present disclosure is not limited thereto, and the optical axis of the first laser light L1 and the optical axis of the second laser light L2 may not coincide with each other, and the first laser light L1 and the second laser light L2 may be rotated by separate laser scanning optical systems (galvano scanners). That is, the present disclosure also includes a configuration in which the laser device 100 includes two galvano scanners, one galvano scanner rotates the first laser light L1, and the other galvano scanner rotates the second laser light L2.

WELDING METHOD AND LASER DEVICE

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