阅读说明：本技术 部件的制造方法 (Method for manufacturing component ) 是由 阿津地真也 于 2020-09-29 设计创作，主要内容包括：一种部件的制造方法,其利用沿着焊接线照射激光而实施焊接的激光焊接,来制造使多个母材彼此熔接而形成的部件。该部件的制造方法包括：在开始实施沿着焊接线的焊接之前,在焊接线起始地点的附近,使激光的照射位置至少在第1地点和第2地点之间反复移动,并在反复移动的过程中提高激光的输出功率,其中,第1地点是所述起始地点,第2地点是与第1地点不同的地点。(A method for manufacturing a component by welding a plurality of base materials to each other by laser welding in which laser light is irradiated along a welding line to perform welding. The method of manufacturing the component includes: before starting welding along a welding line, the irradiation position of the laser is repeatedly moved at least between a 1 st spot and a 2 nd spot in the vicinity of the starting spot of the welding line, and the output power of the laser is increased during the repeated movement, wherein the 1 st spot is the starting spot and the 2 nd spot is a spot different from the 1 st spot.)

1. A method of manufacturing a component by welding a plurality of base materials to each other by laser welding in which laser light is irradiated along a welding line to perform welding, the method comprising:

before starting welding along the welding line, repeatedly moving the irradiation position of the laser between at least a 1 st position and a 2 nd position in the vicinity of the starting position of the welding line, and increasing the output power of the laser during the repeated movement, wherein the 1 st position is the starting position, and the 2 nd position is a position different from the 1 st position.

2. The method of manufacturing a component according to claim 1, comprising:

repeatedly moving the irradiation position of the laser beam at least between the 1 st spot and the 2 nd spot in the vicinity of the starting spot before starting welding along the weld line, and increasing the output of the laser beam during the repeated movement, thereby forming an initial weld pool at the starting spot; and

irradiating the laser along the weld line from the starting point where the initial weld pool is formed.

3. The method of manufacturing a component according to claim 1 or 2, comprising:

repeatedly moving the irradiation position of the laser light at least between the 1 st spot and the 2 nd spot in the vicinity of the starting spot before starting to perform welding along the weld line, and increasing the output power of the laser light to a target output power of the welding along the weld line during the repeated movement.

4. The method for manufacturing a member according to any one of claims 1 to 3,

the irradiation spot of the laser light at the 2 nd site and the irradiation spot of the laser light at the 1 st site at least partially coincide.

5. The method for manufacturing a member according to any one of claims 1 to 4,

the irradiation position of the laser beam is moved between the 1 st spot and the 2 nd spot in a reciprocating manner.

6. The method for manufacturing a member according to any one of claims 1 to 5,

a straight line passing through the 1 st and 2 nd locations intersects a tangent line of the weld line at the 1 st location.

7. The method for manufacturing a member according to any one of claims 1 to 6,

a straight line passing through the 1 st and 2 nd locations is orthogonal to a tangent of the weld line at the 1 st location.

8. The method for manufacturing a member according to any one of claims 1 to 7,

the laser is fiber laser.

Technical Field

The present disclosure relates to a manufacturing method of manufacturing a part using laser welding.

Background

In laser welding, as the output of laser light for irradiating a base material is increased, welding spatter is more likely to be generated. The welding spatter is a molten material which is spattered from a molten portion which is locally at a high temperature on the surface of the base material to the periphery by irradiating the base material with a laser beam having a high energy density. If the splashed molten material adheres to the base material or the like as foreign matter, the quality of the produced component may be degraded.

As a method for suppressing the generation of welding spatter, japanese patent application laid-open No. 2017-164811 describes the following method: the laser beam irradiation is started at the start position of welding at an output power at which welding spatter is not generated, and the laser beam scanning is not performed after the laser beam irradiation is started, but the output power of the laser beam is gradually increased so that the penetration depth falls within a predetermined penetration depth range.

Disclosure of Invention

However, the method described in japanese patent application laid-open No. 2017-164811 is premised on slowly increasing the output of the laser light so as not to generate welding spatter, and therefore, this method cannot satisfy the demand for increasing the output to a high output in a short time so as to shorten the cycle of the welding process.

An aspect of the present disclosure provides a method of manufacturing a component by laser welding, which can improve output in a short time while suppressing generation of welding spatter.

Technical scheme for solving problems

One aspect of the present disclosure is a method of manufacturing a component by welding a plurality of base materials to each other by laser welding in which laser light is irradiated along a welding line to perform welding. The method of manufacturing the component further comprises: before starting welding along a welding line, the irradiation position of laser is repeatedly moved at least between a 1 st position and a 2 nd position in the vicinity of the starting position of the welding line, and the output power of the laser is increased during the repeated movement, wherein the 1 st position is the starting position, and the 2 nd position is a position different from the 1 st position.

According to the above configuration, the output power can be increased in a short time while suppressing the generation of welding spatter.

In one aspect of the present disclosure, a method of manufacturing a component may include: before starting welding along the welding line, repeatedly moving the irradiation position of the laser between at least the 1 st spot and the 2 nd spot near the starting spot, and increasing the output power of the laser during the repeated movement, thereby forming an initial molten pool at the starting spot; and irradiating laser along the welding line from the starting point where the initial molten pool is formed.

In one aspect of the present disclosure, a method of manufacturing a component may include: before starting welding along the welding line, the irradiation position of the laser is repeatedly moved at least between the 1 st spot and the 2 nd spot in the vicinity of the starting spot, and the output power of the laser is increased to the target output power of the welding along the welding line during the repeated movement.

In one aspect of the disclosure, the irradiation spot of the laser light at the 2 nd site and the irradiation spot of the laser light at the 1 st site may at least partially coincide. According to the above configuration, a desired penetration depth can be easily ensured.

In one aspect of the present disclosure, the irradiation position of the laser light may be moved between the 1 st spot and the 2 nd spot in a reciprocating manner.

In one aspect of the present disclosure, a straight line passing through the 1 st and 2 nd locations may intersect a tangent line of the welding line at the 1 st location. According to the above configuration, the melt can easily flow from the initial molten pool to the weld line, and the welding quality can be improved.

In one aspect of the present disclosure, a straight line passing through the 1 st and 2 nd locations may be orthogonal to a tangent of the weld line at the 1 st location. According to the above configuration, the melt flows more easily from the initial molten pool to the weld line.

In one aspect of the present disclosure, the laser may be a fiber laser. Since the fiber laser having a high energy density tends to easily generate welding spatter, the above-described method for manufacturing a member by laser welding is particularly effective for a method using a fiber laser as a laser.

Drawings

Fig. 1A is a view illustrating a method of manufacturing a component by laser welding, as viewed from a side surface of the component.

Fig. 1B is a view illustrating a method of manufacturing a component by laser welding, as viewed from the surface of the base material.

Fig. 2A is a diagram illustrating a method of forming an initial molten pool.

Fig. 2B is a diagram illustrating a method of forming an initial molten pool.

Fig. 2C is a diagram illustrating a method of forming an initial molten pool.

Fig. 2D is a diagram illustrating a method of forming an initial molten pool.

Fig. 2E is a diagram illustrating a method of forming an initial molten pool.

Fig. 3 is a diagram illustrating a method of setting the initial output power of the laser.

Fig. 4A is a diagram illustrating a modification of the method of increasing the laser output power.

Fig. 4B is a diagram showing a modification of the method of increasing the laser output power.

Fig. 5A is a diagram showing a modification of the laser reciprocation method.

Fig. 5B is a diagram showing a modification of the laser reciprocation method.

Fig. 5C is a diagram showing a modification of the laser reciprocation method.

Description of reference numerals:

1. 2 … parent material; 3 … laser; 4 … automotive parts; l … weld line; m … extension line;

s … irradiating a light spot; WP₀… initial molten pool; x1 … location 1 (start location);

x2 … Point 2

Detailed Description

Exemplary embodiments of the present disclosure are described below with reference to the accompanying drawings.

[1. method for producing component ]

In the method for manufacturing a component, a component formed by welding a plurality of base materials to each other is manufactured by laser welding. Specifically, as shown in fig. 1A, a laser 3 is irradiated onto two flat plate-shaped base materials 1 and 2 stacked together, and thereby a surface of the base material 1 and a surface of the base material 2 are welded to each other, thereby manufacturing an automobile member 4, and a part of the automobile member 4 has a structure in which the two base materials 1 and 2 are stacked together. As an example, stainless steel is used as base material 1 and base material 2.

As shown in fig. 1B, laser welding is performed by irradiating laser light along a welding line L. Specifically, the laser light is scanned from the start point X1 of the welding line L so as to pass through the welding line L. The welding line L is a line on which welding is to be performed, and the starting point X1 of the welding line L is a point on the welding line L at which welding is started. For example, the welding line L has a shape extending linearly from the start point X1.

As an example, a fiber laser is used as the laser light.

Before starting to perform welding along the weld line L, an initial weld puddle WP0 is first formed at the start point X1. The molten pool refers to a portion of the base material that is melted by the irradiation of the laser beam, and the initial molten pool WP0 refers to a molten pool formed at the start point X1. The method of forming the initial molten pool WP0 will be described in detail below.

Then, the laser beam is irradiated at the target output power PT along the welding line L from the start point X1 where the initial molten pool WP0 is formed. Specifically, the laser beam is irradiated on the welding line L from the start point X1 toward an end point, not shown, of the welding line L.

In the vicinity of the start point X1, the irradiation position of the laser beam is moved back and forth between two points, i.e., a start point X1 (hereinafter referred to as "1 st point X1") and a 2 nd point X2 different from the 1 st point X1, and the output power P of the laser beam is increased stepwise from an initial output power P0 lower than the target output power PT to the target output power PT while the movement is repeated, thereby forming an initial molten pool WP 0. Specifically, the initial molten pool WP0 is formed by the following method.

First, as shown in fig. 2A, the position of the welding head to which the laser irradiation unit is attached is set so as to irradiate the 1 st spot X1 with laser light. At this stage, the laser irradiation of the base material has not yet started. Fig. 2A shows a graph showing the output power P of the laser light as a function of time, and the arrows in the graph show the current stages in the method of forming the initial molten pool WP 0. Fig. 2B to 2E below are also illustrated in the same manner.

Next, as shown in fig. 2B, the output of the laser beam is increased to the initial output P0, and the irradiation of the base material with the laser beam is started. At this time, as shown by the irradiation spot S in fig. 2B, the laser light is irradiated to the 1 st spot X1.

Then, as shown in fig. 2C, the irradiation position of the laser beam is moved from the 1 st spot X1 to the 2 nd spot X2 while keeping the output power P of the laser beam at the initial output power P0.

The 2 nd spot X2 is a spot near the start spot X1 (the 1 st spot X1), specifically, the 2 nd spot X2 is a spot closer to the start spot X1 to form an initial molten pool WP0 having a desired size at the start spot X1. The size of the initial molten pool WP0 described herein includes both the area and the penetration of the initial molten pool WP0 on the surface of the base material. The penetration is a depth from the surface of the base material in the laser irradiation direction of the molten pool formed on the base material.

Further, as shown in fig. 1B, the 2 nd point X2 is not on the extension line M of the welding line L, but is located at a position deviated from the extension line M. That is, a straight line passing through the 1 st spot X1 and the 2 nd spot X2 intersects the welding line L and the extension line M thereof, in other words, intersects the tangent line of the welding line L at the 1 st spot X1. For example, a straight line passing through the 1 st spot X1 and the 2 nd spot X2 is orthogonal to the welding line L and the extension line M thereof.

Next, as shown in fig. 2D, the laser beam output power P is increased by a predetermined output amplitude Δ P with respect to the initial output power P0 while the irradiation position of the laser beam is maintained at the 2 nd spot X2.

Then, as shown in fig. 2E, the irradiation position of the laser beam is moved from the 2 nd spot X2 to the 1 st spot X1 while keeping the output power P of the laser beam at the initial output power P0+ Δ P.

Then, the movement between the 1 st spot X1 and the 2 nd spot X2 and the increase of the output power P of the laser beam by the output amplitude Δ P are repeated until the output power P reaches the target output power PT. When the output power P reaches the target output power PT, the desired initial molten pool WP0 is formed at the start point X1 (the 1 st point X1), and welding along the weld line L can be started from the start point X1 at which the initial molten pool WP0 is formed.

The initial output power P0, the moving distance Δ X between the 1 st spot X1 and the 2 nd spot X2, and the number of times n of movement between the 1 st spot X1 and the 2 nd spot X2 may be adjusted in accordance with the target output power PT, the size of the initial molten pool WP0 to be formed, the target arrival time T from the start of irradiation until the target output power PT is reached, the material and thickness of the base material, the type of laser beam, and the like.

An example of a method for setting the initial output power P0, the movement distance Δ X, and the number of movements n will be described below.

First, the desired penetration depth of the initial molten pool WP0 reached at the target arrival time T and the desired target output power PT are set as rough targets.

Then, the movement distance Δ X is set. Here, if the movement distance Δ X is too large, it is difficult to obtain a desired penetration depth within the target arrival time T.

For example, the movement distance Δ X is preferably equal to or less than the beam diameter of the laser beam. The beam diameter is the diameter of the laser beam on the base material. As shown in fig. 1B, if the movement distance Δ X is less than or equal to the beam diameter, the irradiation spot S1 of the laser light at the 1 st spot X1 and the irradiation spot S2 of the laser light at the 2 nd spot X2 may partially overlap, and thus it is easy to ensure a desired penetration depth. The movement distance Δ X is, for example, approximately several hundred nm or more and several mm or less with respect to a beam diameter of several μm or more and several tens mm or less.

The number of times of movement n is not particularly limited, and for example, the movement speed VX between the 1 st spot X1 and the 2 nd spot X2 may be set to be equal to the welding speed, that is, the movement speed VL of the laser beam when welding is performed along the welding line L. That is, if the moving speed VX is set, the number of times of movement n can be naturally derived by dividing the product of the moving speed VX and the target arrival time T by the moving distance Δ X. The number of times of movement is, for example, about several tens to several thousands of times.

The initial output power P0 is a value smaller than the target output power PT and can be set as appropriate. However, if the initial output power P0 is too large, welding spatter may be generated. If the initial output power P0 is too small, it becomes difficult to obtain a desired penetration depth within the target arrival time T. The initial output P0 is preferably set to an output that does not generate welding spatter, and more specifically, is preferably set to an output that does not generate welding spatter when the method for forming the initial weld pool WP0 is performed.

An appropriate value of the initial output power P0 may be obtained by: the method of forming the initial molten pool WP0 is performed in real time in accordance with the conditions such as the set target arrival time T, the set movement distance Δ X, and the set number of movements n, and it is checked whether or not a desired penetration depth can be obtained and whether or not welding spatter is generated.

For example, fig. 3 shows the test results when the value of the initial output power P0 is variously changed under the above setting conditions when the target arrival time T is set within a certain range. In this test, whether or not the melt pool penetrated to the back surface of the base material was observed to determine whether or not the melt pool reached a desired penetration depth. As shown in fig. 3, weld spatter is generated in a region a where the initial output P0 is relatively high. In the region B where the initial output power P0 is relatively low and the target arrival time T is relatively short, no penetration occurs. On the other hand, in the region C where the initial output P0 is relatively low and the target arrival time T is relatively long, penetration occurs without generating welding spatter. From the viewpoint of safety, a relatively low value may be set as the initial output power P0 from among the appropriate values of the above-described region C.

The initial output power P0, the movement distance Δ X, and the number of movements n can be set as described above. When the number of times of movement n and the initial output power P0 are set, the output amplitude Δ P is naturally derived by dividing the difference obtained by subtracting the initial output power P0 from the target output power PT by the number of times of movement n.

[2. Effect ]

The following effects can be obtained according to the embodiments described in detail above.

(2a) In the above embodiment, before the welding along the welding line L is started, the irradiation position of the laser light is repeatedly moved at least between the 1 st spot X1 and the 2 nd spot X2 different from the 1 st spot X1 in the vicinity of the starting spot X1 (the 1 st spot X1) of the welding line L, and the output of the laser light is increased during the repeated movement. According to the above configuration, compared to the case where the output power of the laser beam is rapidly increased without moving the irradiation position of the laser beam at the start point X1, the heat concentration at the start point X1 can be suppressed, and the temperature of the molten portion can be suppressed from rapidly increasing. Therefore, abrupt vaporization of the melt can be suppressed, and generation of welding spatter can be suppressed. Further, the output power can be increased in a short time as compared with the case where the output power of the laser beam is increased slowly without moving the irradiation position of the laser beam at the start point X1 in order to suppress the generation of the welding spatter.

(2b) In the above embodiment, the irradiation spot S2 of the laser light at the 2 nd spot X2 and the irradiation spot S1 of the laser light at the 1 st spot X1 at least partially overlap. According to the above configuration, a desired penetration depth can be easily ensured.

(2c) In the above embodiment, the straight line passing through the 1 st spot X1 and the 2 nd spot X2 intersects the welding line L and the extension line M thereof. In other words, a straight line passing through the 1 st place point X1 and the 2 nd place point X2 intersects with a tangent line of the welding line L at the 1 st place point X1. According to the above configuration, the initial molten pool WP0 is formed close to the weld line L, as compared with the case where the 2 nd spot X2 is on the extension line M of the weld line L, that is, the case where the straight line passing through the 1 st spot X1 and the 2 nd spot X2 does not intersect with the tangent line of the weld line L at the 1 st spot X1. Therefore, the melt easily flows from the initial molten pool WP0 to the weld line L, and the welding quality can be improved. In particular, in the above embodiment, since the straight line passing through the 1 st spot X1 and the 2 nd spot X2 is orthogonal to the welding line L and the extension line M thereof, the melt is more likely to flow from the initial molten pool WP0 to the welding line L.

(2d) In the above embodiment, the laser light is a fiber laser light. The fiber laser has excellent light collecting properties compared to other laser light used for welding, for example, YAG laser, and has a high energy density applied to a welded joint. Therefore, welding using a fiber laser as a laser tends to generate weld spatter more easily than other laser welding. The method for manufacturing a member by laser welding according to the above-described embodiment can suppress the generation of welding spatter, and therefore, the method is particularly effective for welding using a fiber laser as a laser.

[3 ] other embodiments ]

The present disclosure is not limited to the above-described embodiments, and may be implemented in various ways.

(3a) In the above embodiment, the output power of the laser light is increased in stages, but the method of increasing the output power is not limited to this. For example, as shown in fig. 4A, the output power can be increased linearly. In the above embodiment, the output power of the laser light is increased at a fixed output amplitude, but the output amplitude may be different. For example, as shown in fig. 4B, the step of increasing the output power of the laser may be divided into two stages, and the output amplitude in the latter half stage may be made larger than that in the former half stage.

(3b) In the above embodiment, the irradiation position of the laser light is moved between the two positions of the 1 st position X1 and the 2 nd position X2 in a reciprocating manner, but the moving method of the irradiation position of the laser light is not limited to this. For example, the laser may be moved between three locations, as shown in fig. 5A, or between four locations, as shown in fig. 5B. Further, as shown in fig. 5C, the laser light may be moved in such a manner that an arc is drawn from the 1 st point X1, which is the starting point of the welding line L, and passes through the 2 nd point X2 and then returns to the 1 st point X1. In the case shown in fig. 5C, since the laser beam moves smoothly, the molten material is less likely to be splashed from the initial molten pool WP0 than in the cases shown in fig. 5A and 5B. The 2 nd spot X2 in the above case as shown in fig. 5A to 5C is a spot farthest from the 1 st spot X1 in the path through which the irradiation position of the laser light passes.

(3c) In the above embodiment, the 2 nd spot X2 is at a position such that a straight line passing through the 1 st spot X1 and the 2 nd spot X2 is orthogonal to the welding line L and the extension line M thereof, but the position of the 2 nd spot X2 is not limited thereto. For example, the 2 nd place X2 may be on the extension line M of the welding line L, and the 2 nd place X2 may also be at a position such that a straight line passing through the 1 st place X1 and the 2 nd place X2 intersects the welding line L and the extension line M thereof at an arbitrary angle.

(3d) In the above embodiment, the weld line L is linear, but the shape of the weld line L is not limited thereto. For example, the weld line L may be curved. In the above embodiment, since the weld line L is linear, the tangent of the weld line L at the 1 st point X1 has the same meaning as the weld line L and the extension line M thereof.

(3e) The output power of the laser light irradiated along the welding line L does not have to be a fixed output power on the welding line L, and the laser light may be irradiated on the welding line L in such a manner that the output power of the laser light is changed. That is, the target output power PT is the target output power of the laser beam at the start of welding.

(3f) In the above embodiment, the irradiation position of the laser light is moved from the 1 st spot X1 to form the initial molten pool WP0, but the start movement position of the irradiation position of the laser light is not limited thereto. For example, the irradiation position of the laser beam may be moved from the 2 nd spot X2.

(3g) In the above embodiment, the moving speed VX between the 1 st point X1 and the 2 nd point X2 is equivalent to the welding speed VL, but may be different from each other.

(3h) In the above embodiment, the laser light is a fiber laser light, but the type of laser light is not limited thereto. For example, the laser may be a CO2 laser, a YAG laser, a semiconductor laser, a laser diode pumped solid state laser (including a disk laser), or the like.

(3i) In the above embodiment, the base material is stainless steel, but the material of the base material is not limited thereto. For example, the base material may be aluminum-plated steel, copper-plated steel, aluminum alloy, copper alloy, or the like, in addition to the stainless steel.

(3j) In the above-described embodiment, the so-called lap joint is formed by performing penetration welding on the surfaces of the base materials that are stacked on each other, but the structure formed by laser welding is not limited thereto. For example, the structures formed using laser welding may be butt joints, corner joints, end joints, T-joints formed by penetration welding, T-joints formed by corner welding, lap joints formed by corner welding, and the like. In the above embodiment, the base material is irradiated with the laser beam perpendicularly to perform welding, but the angle of irradiation of the laser beam is not limited to this. The method of the above embodiment can be applied to various welding methods.

(3k) The automobile member 4 was manufactured in the above embodiment. The manufactured automotive component 4 may be, for example, an instrument panel reinforcement or the like. The component to be manufactured is not limited to the automobile member 4, and may be, for example, a household electrical appliance component.

(3l) the function of one constituent element in the above-described embodiment may be shared by a plurality of constituent elements, or the functions of a plurality of constituent elements may be integrated into one constituent element. Further, a part of the configuration of the above embodiment may be omitted. Further, at least a part of the configuration of the above embodiment may be added to the configuration of the above other embodiment, or at least a part of the configuration of the above embodiment may be replaced with the configuration of the above other embodiment.