JP2011031256A - Apparatus for supplying filler wire in laser welding and method for supplying the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus for supplying filler wire capable of suitably fusing filler wire from the start of welding so as to stabilize a laser welding state when carrying out laser welding while supplying the filler wire to portions of a plurality of metal members to be welded, and also to provide a method for supplying the filler wire. <P>SOLUTION: The apparatus for supplying the filler wire has a heating device for heating the filler wire X by energization. The heating device includes: first rollers 51A, 51B contacting with a part in the vicinity of the end of the filler wire X; second rollers 61A, 62B arranged at positions set apart therefrom; a clamp contacting with metal plates W1, W2; and a power supply device 31 for causing energization through the filler wire X between the first rollers 51A, 51B and the second rollers 61A, 61B at the start of supplying the filler wire X and causing energization through the filler wire X and the metal plates W1, W2 between the first rollers 51A, 51B and the clamp 5 after a predetermined time from the start of supplying. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a filler wire supply apparatus and a supply method for supplying a filler wire to a welded portion by laser light when laser welding a plurality of metal members, and belongs to the technical field of laser welding.

  In recent years, laser welding is being used as a welding method for a plurality of metal members. In this laser welding, a laser beam irradiated portion of a plurality of metal members is moved by moving the laser beam with respect to the metal member along a predetermined welding path while irradiating the laser beam toward the surface of the metal member. It is melted to form a linear weld bead.

  Here, there may be a gap between the metal members. In this case, the metal members may not be joined together due to lack of molten metal. As a method for solving this problem, a method is known in which a filler wire is supplied so as to follow the movement of the irradiated portion of the laser beam, the wire is melted, and the molten metal is increased.

  In order to improve the meltability of the filler wire during welding, the filler wire is heated. Specifically, as disclosed in Patent Literature 1, Joule heat is generated and heated by energizing a portion near the end of the filler wire during welding. More specifically, at the time of welding, the end of the filler wire comes into contact with the welded portion of the metal member. Therefore, a plus electrode is brought into contact with a portion near the end of the filler wire, a minus electrode is brought into contact with the metal member, and a voltage is applied between both electrodes in this state. Thereby, the end side part in the filler wire is energized through the metal member.

  By the way, before the start of welding, for example, for the installation of a metal member, the end of the filler wire is in a state of being separated from the metal member to be welded. As a result, after starting welding and supplying filler wire, the filler wire is not heated until the end of the filler wire comes into contact with the welded portion of the metal member and energization is started. Therefore, the filler wire is not sufficiently melted at the welded part, and the unmelted filler wire may remain at the welded part. Moreover, there is a possibility that the welding state thereafter becomes unstable as a result. For this problem, measures such as supplying the filler wire in advance so as to be in contact with the metal plate before the start of welding can be considered, but there are problems such as complicated supply control of the wire. Further, separately performing such control before the start of welding has problems such as extra welding time.

  With respect to this problem, in the welding apparatus according to Patent Document 1, until the end of the filler wire comes into contact with the metal member at the start of welding, the gap between the end of the filler wire and the arc electrode or the metal material. It is disclosed that electricity is heated by generating an arc to heat.

JP 2002-103040 A

  By the way, since the welding apparatus according to Patent Document 1 is a TIG welding apparatus, an arc can be generated. However, in the case of a laser welding apparatus, an arc cannot be generated. There is a problem of how to cope with the above-described problem until the portion contacts the metal member.

  Therefore, the present invention makes it possible to melt the filler wire satisfactorily from the start of welding when the laser welding is performed while supplying filler wires to the welded portions of a plurality of metal members, thereby stabilizing the laser welding state. It is an object of the present invention to provide a filler wire supply device and a supply method that can be used.

  In order to solve the above-described problems, the present invention is configured as follows.

  First, the invention according to claim 1 of the present application is to follow a state in which an end portion is in contact with a portion to be welded by a laser beam that moves relative to a plurality of metal members along a predetermined welding path. A filler wire supply device for supplying a filler wire, comprising a heating means for heating the filler wire by energizing the filler wire, the heating means being in contact with a portion near the end of the filler wire; A second electrode that is in contact with the filler wire at a position spaced from the first electrode, a third electrode that is in contact with at least one of the metal members, and at the start of supply of the filler wire, the first electrode A current is passed between the electrode and the second electrode through a filler wire, and after a predetermined time after the supply is started, a gap is formed between one of the first electrode and the second electrode and the third electrode. Characterized in that it comprises energizing means for energizing through Rawaiya and metal member.

  Further, the invention according to claim 2 is the filler wire supply device in laser welding according to claim 1, wherein after the filler wire starts to be fed, the end of the wire comes into contact with the welded portion. Contact detection means for detecting is provided, and the predetermined time after the start of supply is when contact of the end is detected by the contact detection means.

  Further, the invention according to claim 3 is the filler wire supply device in laser welding according to claim 1, further comprising a time measuring means for measuring an elapsed time from the start of supply of the filler wire, The predetermined time after the start of supply is a time when the time measured by the time measuring means reaches a predetermined time.

  According to a fourth aspect of the present invention, there is provided the filler wire supply apparatus for laser welding according to any one of the first to third aspects, wherein the filler wire supply means is configured to supply the filler wire to the laser. Supplying at a position behind the laser beam irradiated site so that the end of the molten pool is formed in the welded site by light and where molten metal is stored, the heating means, The filler wire is heated so as to melt with the heat of the molten pool when contacting the molten pool.

  The invention according to claim 5 is the filler wire supply device in laser welding according to any one of claims 1 to 4, wherein each of the first electrode and the second electrode is the filler wire. It is comprised by the roller which supports so that a movement is possible.

  According to a sixth aspect of the present invention, in the filler wire supply apparatus in laser welding according to the fifth aspect, each of the rollers constituting the first electrode and the second electrode is composed of a pair of upper and lower rollers. At the same time, it is configured to be able to assist the transfer of the filler wire supplied from the upstream side by being driven by the driving means, and the roller constituting the first electrode is a roller constituting the second electrode It is characterized by being driven so as to have a faster supply speed.

  According to a seventh aspect of the present invention, there is provided a filler wire such that a plurality of metal members follow a welded portion by a laser beam that moves relatively along a predetermined welding path in a state where the end portion is in contact. A filler wire supplying method for heating the filler wire by energizing the filler wire, wherein the heating step contacts a portion near the end of the filler wire at the start of supplying the filler wire The first electrode is energized via the filler wire between the first electrode that is in contact with the second electrode that is in contact with the first electrode in the filler wire, and after the predetermined time after the supply is started, the first electrode Between the first electrode and the second electrode and the third electrode contacting at least one of the metal members through a filler wire and a metal member. And butterflies.

  Next, the effect of the present invention will be described.

  First, according to the first aspect of the present invention, in laser welding, a plurality of metal members are tracked in contact with a portion to be welded by a laser beam that moves relatively along a predetermined welding path. Thus, a filler wire is supplied.

  In that case, according to the present invention, the filler wire is energized and heated by the heating means. More specifically, the heating means includes a first electrode that is in contact with a portion near the end of the filler wire, a second electrode that is in contact with the filler wire at a position spaced from the first electrode, and the metal member. A third electrode in contact with at least one of them. Then, at the start of supply of the filler wire at the start of welding, a portion of the filler wire between the first electrode and the second electrode (hereinafter referred to as a predetermined portion for convenience of explanation) is energized. Thereby, Joule heat is generated in the predetermined portion of the filler wire, and the portion is heated. In addition, since the first electrode is in contact with the vicinity of the end portion of the filler wire, when the predetermined portion is heated, the portion closer to the end portion than the predetermined portion is also heated by heat transfer. That is, the filler wire is heated before the end of the filler wire comes into contact with the welded portion of the metal member. Therefore, melting of the filler wire when supplied to the welded part is promoted.

  On the other hand, after a predetermined time after the start of supply, the metal plate in which the third electrode is in contact with a portion of the filler wire that is closer to the end than one of the first electrode and the second electrode. Is energized through. Thereby, Joule heat is generated in the end side portion of the filler wire, and the portion is heated. Therefore, melting of the filler wire at the welded part is promoted.

  In addition, as a method for melting the filler wire in the welded portion, laser beam irradiation to the end of the filler wire or contact of the end of the filler wire with the molten pool can be considered. This is also applicable and effective.

  According to the invention described in claim 2, after the supply of the filler wire is started, it is detected that the end of the filler wire is in contact with at least one of the metal members. The portion closer to the end than the one of the first electrode and the second electrode is energized through a metal plate in contact with the third electrode. Therefore, it is possible to shift from the preliminary heating state to the original heating state required after contact at an accurate timing.

  According to the invention of claim 3, the first electrode and the second electrode in the filler wire after the time measured by the time measuring means reaches a predetermined time after the supply of the filler wire is started. Then, the portion closer to the end than one electrode is energized through a metal plate in contact with the third electrode. This predetermined time is determined based on, for example, the distance between the position of the end of the filler wire before the start of supply and the planned contact position with the metal member and the supply speed of the filler wire. It is set to a time at which the welding part is to be contacted or a time in the vicinity thereof. Therefore, it is possible to shift from the preliminary heating state to the original heating state required after the contact with almost accurate timing. As the time measuring means, a general timer or the like can be used. In this case, the above-described effects can be obtained with a simple configuration.

  According to a fourth aspect of the present invention, the laser beam is formed such that the filler wire is brought into contact with a molten pool formed at the irradiated portion of the laser beam and in which molten metal is stored. In the case where the filler wire is heated so as to be melted with the heat of the molten pool when it is supplied from a position behind the light irradiated portion and comes into contact with the molten pool, the actions and effects of the above claims are can get. That is, when the filler wire is melted not by laser light but by the heat of the molten pool, if the filler wire is not sufficiently heated, the filler wire may not be melted satisfactorily. However, this possibility can be satisfactorily eliminated by applying the inventions described in the above claims.

  Further, according to the invention of claim 5, since each of the first electrode and the second electrode is configured by a roller that supports the filler wire so as to be movable, while supporting the movement of the filler wire, An electric current can be passed through the filler wire. That is, the electrode and the support can be shared by one member, and the parts constituting the filler wire supply device can be reduced.

  According to a sixth aspect of the present invention, each of the rollers constituting the first electrode and the second electrode is composed of a pair of upper and lower rollers, and is driven by the driving means so that the rollers are arranged from the upstream side. Since it is configured to be able to assist the transfer of the filler wire to be supplied, and the roller constituting the first electrode is driven to have a higher supply speed than the roller constituting the second electrode, It is possible to prevent the filler wire from loosening between the roller constituting the first electrode and the roller constituting the second electrode. In addition, by setting the clamping force between the upper and lower rollers constituting the first electrode to a force capable of causing a slip between the filler wire and the roller, the roller constituting the first electrode and the second electrode It is possible to absorb the speed difference between the rollers constituting the.

  Moreover, according to the method invention of Claim 7, the effect | action and effect demonstrated in the apparatus invention of Claim 1 will be acquired.

1 is an external perspective view of a laser welding apparatus according to a first embodiment of the present invention. It is a cross-sectional photograph of the welded part of two metal plates. It is a perspective view which shows the laser beam irradiation site | part of a metal plate in laser welding, and the state of the vicinity. (A): It is a top view which shows the laser beam irradiation site | part of a metal plate in laser welding, and the state of the vicinity. (B): It is AA sectional drawing of the figure (a). (A): BB sectional view of FIG. 4 (b), (b): CC sectional view of FIG. 4 (b), (c): DD sectional view of FIG. 4 (b), (d) ): EE sectional view of FIG. 4 (b), (e): FF sectional view of FIG. 4 (b), (f): GG sectional view of FIG. 4 (b). It is explanatory drawing by the same cross section as FIG.4 (b) for demonstrating an example when a malfunction arises in fusion | melting of a filler wire at the time of a welding start. It is sectional drawing of the front-back direction of a wire heating head. FIG. 9 is a lateral sectional view (HH sectional view of FIG. 7) of the wire heating head. It is a control block diagram of a laser welding apparatus. It is explanatory drawing of the effect | action at the time of a welding start. It is explanatory drawing of the effect | action in the predetermined time after the welding start.

  Hereinafter, a laser welding method and a laser welding apparatus according to an embodiment of the present invention will be described.

  FIG. 1 is an external perspective view of a laser welding apparatus 1 according to the present embodiment. The laser welding apparatus 1 includes a laser head 2 that generates a laser beam LB (laser beam), a filler wire supply device 3 that supplies a filler wire X to the rear of a laser beam irradiated position L from the laser head 2, and It has a moving device 4 that supports the laser head 2 and the filler wire supply device 3 and moves it relative to the workpiece W. In addition, as the workpiece | work W, the metal plates W1 and W2 of a cross-sectional hat shape which swelled in the opposite direction mutually and the flanges were piled up and down are shown as an example. Although the flanges of the metal plates W1 and W2 are held by a plurality of clamps 5 ... 5, a gap Z is generated between the opposing surfaces for the accuracy of the metal plates W1 and W2.

  The laser head 2 is configured using a high output laser such as a YAG laser or a carbon dioxide gas laser, and the laser output is variable. The focal position of the laser beam is variable, but is set on the upper surface of the upper metal plate W1 in the present embodiment.

  The filler wire supply device 3 is driven by a wire roll 12 around which a filler wire X is wound, a motor (not shown), a feeding roller 13 that feeds the filler wire X from the wire roll 12, and a target of laser light LB. A wire supply nozzle 11 disposed in the vicinity of the irradiation site L, a filler wire heating head 40 provided at the rear of the nozzle 11 for heating the filler wire X, and between the feeding roller 13 and the filler wire heating head 40 And a tube 14 for guiding the filler wire X fed out by the feeding roller 13 to the heating head 40. The motor is composed of a servo motor capable of controlling the rotation speed, and this makes it possible to adjust the supply amount of the wire X to the welded portion (corresponding to a molten pool WY described later in the present embodiment). ing.

  The moving device 4 is disposed on a support member 21 to which the laser head 2 and the filler wire supply device 3 are attached, a base member 22 attached to the lower end of the support member 21, a factory floor, etc. A rail member 23 that slidably supports the base member 22 and a moving mechanism (not shown) that moves the base member 22 along the rail member 23 are provided. The moving mechanism for moving in this way can be variously configured by known ones and will not be described. However, the drive source is composed of a servo motor (not shown) capable of controlling the rotation speed, and thereby the laser head 11 and The moving speed of the filler wire supply device 3 with respect to the workpiece W can be adjusted.

  Moreover, the laser welding apparatus 1 has a filler wire heating device 6 that heats the filler wire X to a predetermined temperature. The filler wire heating device 6 heats the wire X by Joule heat generated in the wire X by energizing the end of the filler wire X. The heating power supply device 31 and the heating head 40 described above are used. And heating head connection cables 32A and 32B for connecting the heating power supply device 31 and the heating head 40, and a clamp connection cable 33 for connecting the heating power supply device 31 and one of the plurality of clamps 5 ... 5. The current flowing from the heating power supply device 31 returns to the heating power supply device 31 via the heating head connection cables 32A and 32B, the heating head 40, the filler wire X, the metal plates W1 and W2, the clamp 5, and the clamp connection cable 33. It has become. Here, the predetermined temperature is set to a temperature that melts with the heat of the molten pool WY (molten metal Wy) when the end of the filler wire X comes into contact with the molten pool WY described later. The current value for heating the filler wire X to a predetermined temperature may be derived by conducting an experiment or the like. The specific configuration of the filler wire heating device 6 will be described later.

  FIG. 2 is a cross-sectional photograph (one example) in the width direction of a workpiece having good welding strength when two metal plates W1 and W2 having a gap Z are welded while supplying filler wire X. . As can be seen from this photograph, the two metal plates W1 and W2 are connected via a bead WB formed by solidifying the molten metal Wy. Further, on the left and right sides of the bead WB in the width direction, there are heat-affected portions WC1 and WC2 (parts between whitish discoloration on the left and right of the bead WB) in which the metal structure changes in the upper and lower metal plates W1 and W2, respectively. Existing. FIG. 3 is an example, and the upper and lower metal plates W1 and W2 each have a thickness of 1.6 mm and a gap Z of 1.3 mm.

  Here, in such a structure, the upper metal plate W1 melted by the laser beam LB and the molten metal of the filler wire X hang down to the lower metal plate W2 to connect the upper and lower metal plates W1, W2, This molten metal is formed by cooling and solidifying to form a bead WB. The heat affected portions WC1 and WC2 are formed by transferring the heat of the molten metal in the width direction of the metal plates W1 and W2.

  By the way, according to the knowledge of the inventor of the present application, when the filler wire is configured to be melted with laser light, the energy of the laser is consumed to melt the filler wire, for example, the melting of the upper metal plate becomes insufficient, As a result, the molten metal of the filler wire cannot also hang downward, and the upper and lower metal plates may not be connected well by the molten metal. Therefore, in the present embodiment, the filler wire is not melted by laser light, but is melted by the following method.

  First, the outline of the welding method will be described with reference to FIG. 3. The upper metal plate W1 of the two flat plate-like metal plates W1 and W2 in which a gap Z is generated between the surfaces facing each other in a state where they are stacked one above the other. While irradiating the laser beam LB toward the surface, the laser beam LB is moved relative to the two metal W1 and W2 plates along the welding path R, thereby the laser of the upper metal plate W1. The molten portion WK is formed by melting the irradiated portion L and penetrating vertically, and a molten pool WY in which these molten metals are stored in the previously formed molten hole portion is formed behind the welding path R. Let Then, the filler wire X heated so as to be melted by the heat of the molten pool WY has an end portion in the vicinity of the rear of the molten hole WK in the molten pool WY (the specific position of the portion will be described later). Is supplied from the rear of the molten pool WY so as to be in contact with the molten metal, thereby melting the end of the filler wire X and additionally supplying molten metal to the molten pool WY.

  4 and 5, first, in the vicinity of the front of the center LBc of the laser beam LB in the welding path R, as shown in FIGS. 4 (a), 4 (b), and 5 (a), The metal in the vicinity of the laser beam center LBc in the upper metal plate W1 is melted to generate a molten metal Wy. Further, around the molten metal Wy, there is a heat affected zone WC1 in which the metal structure is changed by the heat transmitted from the molten metal Wy. WK is a molten hole (keyhole) formed by pressing the molten metal Wy to the surroundings by the pressure of the metal by the laser beam LB, and the front portion is shown in this figure.

  As shown in FIGS. 4B and 5B, at the position of the laser beam center LBc in the welding path R, the fusion hole WK passes through the upper metal plate W1 and reaches the lower metal plate W2. ing. Also in the lower metal plate W2, the metal in the vicinity of the laser beam center LBc is melted, and the molten metal Wy is generated. The molten metal Wy of the upper metal plate W1 starts to hang down to the lower metal plate W2 side due to gravity. A heat affected zone WC2 is generated around the molten metal Wy of the lower metal plate W2.

  As shown in FIGS. 4B and 5C, in the vicinity of the rear of the laser beam center LBc in the welding path R, the molten metal Wy of the upper metal plate W1 hangs further downward due to gravity. Since the metal Wy is agglomerated by surface tension, the upper metal plate W1 and the lower metal plate W2 are not connected.

  As shown in FIGS. 4B and 5D, the molten metal Wy is stored in the previously formed molten hole at a position behind the laser beam center LBc in the welding path R. As a result, a molten pool WY is formed.

  Also, as shown in FIGS. 4B and 5D, in the present embodiment, the filler wire X heated to melt with the heat of the molten pool WY as described above is melted. From the rear of the pond WY, the end thereof is supplied so as to come into contact with the vicinity of the rear of the molten hole WK in the molten pool WY, and the end of the wire X is melted to generate molten metal Wy ′. Then, the newly generated molten metal Wy ′ is supplied into the molten pool WY, whereby the molten metal Wy in the molten pool WY that originally existed is pushed downward, and the molten metal Wy The downward drooping over the gap Z is promoted, and the upper metal plate W1 and the lower metal plate W2 are connected by the molten metal Wy, Wy ′. Then, as shown in FIGS. 4B and 5E, the molten metal Wy in the molten pool WY starts to solidify from below at a position further rearward than the laser beam center LBc in the welding path R. As shown in FIG. 5 (f), further, the molten metal in the molten pool WY is all solidified from the top to the bottom, and a weld having a cross section as shown in FIG. 2 is formed.

  Here, the supply conditions of the filler wire X will be described in detail. As shown in FIGS. 3, 4A, and 4B, the filler wire X is indicated by an arrow β (described in FIG. 4B). As shown, the end side is supplied along the welding path R so as to be in contact with the molten pool WY while being inclined forward and downward. More specifically, the front end position of the portion of the filler wire X that intersects the upper surface of the upper metal plate W1 is supplied at a distance Dx behind the welding path R from the laser beam center LBc. This distance Dx is (1) the end side of the filler wire X is not irradiated with the laser beam LB at the upper surface position of the upper metal plate W1, and (2) the rear end position of the molten hole WK is slightly changed during welding. Even in this case, the end of the filler wire X comes into contact with the molten pool WY, and (3) the distance satisfying the three conditions is set as close as possible from the laser beam center LBc. Note that this position is a position that defines a rear vicinity portion of the molten hole WK in the molten pool WY. In the present embodiment, the distance Dx is set to a distance that is twice the beam diameter of the laser beam LB, for example.

  As described above, according to the present embodiment, the filler wire X is heated so as to be melted with the heat of the molten pool WY, and the end of the filler wire X from the rear side of the laser light irradiated portion L enters the molten pool WY. By being supplied so as to be in contact with the molten pool WY, the molten metal is melted by contact with the molten pool WY. Therefore, the energy of the laser beam LB is not consumed for melting the filler wire X, but exclusively used for melting the metal plate, and the formation of the melted hole WK of the upper metal plate W1 is stabilized. Become. That is, the structure for allowing the molten metal Wy (Wy ′) of the upper metal plate W1 and the filler wire X to hang down to the lower metal plate W2 side is stably formed. Moreover, the molten metal Wy ′ of the filler wire X generated by the contact with the molten pool WY pushes the molten metal Wy originally present in the molten pool WY downward, so that the molten pool WY is melted. The downward drooping over the gap Z of the metal Wy is promoted, so that the upper and lower metal plates W1, W2 are stably and well connected. The phenomenon of promotion of the downward droop of the molten metal Wy can be understood as the molten metal Wy being injected into the gap Z and moving so as to satisfy the same as a caulking material.

  Further, in the present embodiment, since the filler wire X is supplied so that the end portion is in contact with the rear vicinity portion of the molten hole WK in the molten pool WY, the filler wire X is particularly high in the molten pool WY. Will come into contact with the molten metal Wy. Therefore, the end portion of the wire X is melted well.

  Here, when the distance Dx is defined as described above, when the rear end of the molten hole portion WK largely recedes, the end portion of the filler wire X does not contact the molten pool WY, and the heat with the molten pool WY However, in this embodiment, the filler wire X contacts the molten pool WY in a state where the end side is inclined along the welding path R and forwardly downward. When the end of the wire X is not melted in the molten pool WY, the end reaches the irradiated portion L of the laser beam LB and is melted by the irradiation of the laser beam LB. Become. That is, even if the end portion of the filler wire X is not melted in the molten pool WY, the filler wire X is prevented from being melted. As shown in FIG. 4B, the laser beam can be obtained by setting the intersection position of the laser beam center LBc and the center line Xc of the filler wire X to be lower than the upper metal plate W1. With LB, it is possible to melt the filler wire X while favorably melting the upper metal plate W1.

  By the way, as explained in the section of the problem to be solved, in order to energize the portion near the end of the filler wire, it is necessary to bring the end of the filler wire into contact with the metal member. In some cases, the end of the filler wire must be separated from the metal member before the start, and in this case, there is a possibility that the subsequent welding state becomes unstable.

  Therefore, in the filler wire supply device of the present embodiment, when laser welding is performed while supplying filler wires to the welded portions of a plurality of metal members, the filler wires are melted well from the start of welding, and laser welding is performed. It is comprised so that a state can be stabilized.

  More specifically, as shown in FIGS. 7 and 8, in the filler wire supply device 3 according to the present embodiment, the wire heating head 40 of the filler wire heating device 6 includes a box-shaped housing 41 and an inside of the housing 41. And a pair of upper and lower first rollers 51A and 51B that are in contact with the vicinity of the end of the filler wire X, and are also housed in the housing 41 and spaced apart from the first rollers 51A and 51B. It has a pair of upper and lower second rollers 61A and 61B that contact the filler wire X.

  The first rollers 51A, 51B are rotatably supported by a pair of support members 52, 52 spanned between the upper and lower walls in the casing 41 on the side thereof via support shafts 53A, 53B. . On the inner surface of the upper wall of the housing 41, an electrode 55 is attached above the first rollers 51A and 51B via an insulating material 54, and the electrode 55 is in contact with the upper first roller 51A. The first cable 32 </ b> A of the heating head connection cables 32 is connected to the electrode 55. The electrode 55 is made of, for example, a carbon material.

  The upper roller 51A of the first roller is formed of a metal material, and the lower roller 51B is formed of ceramics. The upper roller 51A is fixed to the support shaft 53A via an insulating material 56.

  The upper support shaft 53A is configured to be rotatable. More specifically, a gear 57 is fixed to one end of the upper support shaft 53A, and a motor 59 having a gear 58 meshing with the gear 57 at one end of the drive shaft 59a is attached to one support member 52. It has been. The rotation of the motor 59 is controlled by a control unit 100 described later.

  The support shaft 53B of the lower roller 51B is supported so as to be movable up and down within a predetermined range with respect to the support member 52, and is urged toward the upper roller 51A via an urging means (not shown). As a result, the filler wire X is sandwiched from above and below by the upper roller 51A and the lower roller 51B.

  The second rollers 61A and 61B and their support structure are the same as those of the first rollers 51A and 51B. Therefore, explanation is omitted. In the drawings, corresponding parts are numbered in the 60s.

  The setting of the distance in the wire longitudinal direction between the first rollers 51A and 51B and the second rollers 61A and 61B will be described in the description of the operation described later.

  As shown in FIG. 9, the laser welding apparatus 1 according to the present embodiment is fixed to a control unit 100 that performs welding control and a support member 21 of the moving device 4, and a laser light irradiation site L of the workpiece W is provided. And an imaging device 110 that images the vicinity thereof from above.

  The imaging device 110 is constituted by, for example, a CCD camera that can acquire an image (capable of acquiring a moving image) at predetermined intervals, and the acquired image is output to the control unit 100 each time. The support member 21 of the moving device 4 is provided with a lamp 9 that illuminates the laser light irradiated portion L and the vicinity thereof on the upper metal plate W1. The lamp 9 is disposed on the opposite side of the imaging device 110 across the welding path R, and illuminates the laser light irradiated portion L and the vicinity thereof on the metal plate W1 obliquely from above. As the lamp 9, for example, a xenon lamp can be used.

  The filler wire heating power supply device 31 includes a selector switch 31 a that is controlled to be switched based on a signal input from the control unit 100. Specifically, when a welding start signal is input from the control unit 100, the filler wire heating power supply device 31 switches so that the changeover switch 31a connects the negative terminal of the power supply 31b and the heating head connection cable 32B side. It is done. On the other hand, when a switch switching control signal is input from the control unit 100, the selector switch 31a is switched so as to connect the minus terminal of the power source 31b and the clamp connection cable 32B side. Various switches such as a mechanical switch and a semiconductor switch can be used as the changeover switch 31a.

  The control unit 100 outputs a rotation speed control signal to the motor 24 of the moving device 4 so that the laser head 2 (laser light) moves at a predetermined speed with respect to both metal plates W1 and W2.

  Further, the control unit 100 outputs a rotation speed control signal so that the filler wire X is supplied to the motor 15 of the filler wire supply apparatus 10 at a predetermined speed.

  Further, the control unit 100 supplies the filler wire X to the roller driving motor 59 for the first rollers 51A and 51B of the wire heating head 40 at the same speed as that supplied by the wire supply motor 15 during welding. Thus, a rotation speed control signal is output.

  The control unit 100 supplies the filler wire X to the drive motor 69 for the second rollers 61A and 61B of the wire heating head 40 at a slightly faster speed than the supply by the wire supply motor 15 during welding. The rotation speed control signal is output so that The reason why the speed is slightly increased is to prevent the filler wire X from becoming slack between the first rollers 51A and 51B and the second rollers 61A and 61B. Note that the difference in supply amount generated in the filler wire X due to this speed difference is eliminated by occasional slippage between the first rollers 51A, 51B and the filler wire X.

  Further, the control unit 100 outputs a welding start signal to the filler wire heating power supply device 31 at the start of welding. Further, the control unit 100 analyzes the image input from the imaging device 110 and determines whether or not the end portion of the filler wire X is in contact with the metal plate W1. And when it determines with the edge part of the filler wire X contacting the metal plate W1, a switch switching control signal is output to the filler wire heating power supply device 31. FIG.

  Next, the operation of the filler wire supply device of the present embodiment will be described.

  When a welding start instruction is input to the control unit 100 via, for example, a welding start operation switch, the control unit 100 includes the laser head 2, the moving device motor 24, the filler wire supply device motor 15, and the first roller. The drive motor 59 and the second roller drive motor 69 are simultaneously operated under predetermined conditions, and a welding start signal is output to the filler wire heating power supply device 31. The predetermined condition is set in advance for each apparatus or is set before starting welding.

  As a result, supply of the filler wire X to the part to be welded by laser light starts, and at the same time, energization by the filler wire heating power supply device 31 starts. In that case, at the start of energization, the changeover switch 31a of the filler wire power supply device 31 is in a position to connect the minus terminal of the power supply 31b and the heating head connection cable 32B side. Therefore, as indicated by an arrow δ in FIG. 10, the heating head connection cable 32A, the electrode 55, and the upper roller 51A of the first roller from the positive terminal of the heating power supply device 31 (the first electrode and the second electrode in the claims). The filler wire X, the roller 61A on the upper side of the second roller (corresponding to the other of the first electrode and the second electrode in the claims), the electrode 65, and the heating head connection cable 32B. Thus, a current route that returns to the negative terminal through the terminal is formed. As a result, Joule heat is generated in the portion of the filler wire X between the first rollers 51A and 51B and the second rollers 61A and 61B, the portion is heated, and the heat is applied to the end of the wire X. Will also be transmitted. In this case, since the first rollers 51A and 51B are in contact with the vicinity of the end portion of the filler wire X at the start of energization, the end side portion is also heated well. That is, in the present embodiment, the filler wire X is heated before its end portion comes into contact with the molten pool WY in the metal plates W1, W2. Therefore, melting of the filler wire X when the filler wire X is supplied to the molten pool WY is promoted. Note that the distance between the first rollers 51A and 51B and the second rollers 61A and 61B in the wire longitudinal direction is such that, when the material of the filler wire X is, for example, iron, the end of the filler wire X contacts the molten pool WY. At the time of moving to the state, the tip temperature of the wire X is set to an interval at which the tip temperature of the wire X increases to about 1100 degrees, for example. Increasing the interval increases the amount of energized power until the end of the filler wire X comes into contact with the molten pool WY, so the amount of heat transferred to the end of the wire X increases and the tip temperature rises. . Note that the melting point of iron is about 1400 degrees, and if the tip temperature is increased to 1100 degrees, good meltability can be ensured when the end of the filler wire X comes into contact with the molten pool WY.

  Further, before the supply of the filler wire X is started, the end of the filler wire X is retracted to the position of Lr at the rear portion of the sleeve 11 as shown in FIG. This is because when the energization of the filler wire X is started (in the state shown in FIG. 10), the end of the wire X is heated as soon as possible. Therefore, the effect is more certain. In the retracted state, the sleeve 11 and the end portion side of the filler wire X overlap each other by a predetermined amount Ls.

  On the other hand, when the control unit 100 determines that the end of the filler wire X is in contact with the molten pool WY (welded part) of the metal plate W1 based on the image captured by the imaging device 110 (claims) The switch switching control signal is input from the control unit 100 to the filler wire heating power supply 31 as indicated by an arrow ε in FIG. Thereby, the changeover switch 31a is switched so as to connect the minus terminal of the power supply 31b and the clamp connection cable 32B side. Then, from the plus terminal of the heating power supply 31, the heating head connection cable 32A, the electrode 55, the roller 51A on the upper side of the first roller (corresponding to one of the first electrode and the second electrode in the claims), filler A current route returning to the minus terminal is formed (that is, energized) through the wire X, the metal plates W1 and W2, the clamp 5 (corresponding to the third electrode in the claims), and the clamp connection cable 33. Therefore, Joule heat is generated in a portion closer to the end portion than the portion in contact with the upper roller 51A in the filler wire X, and the portion is heated. Therefore, melting of the filler wire X when supplied to the molten pool WY is promoted.

  Moreover, when it determines with the edge part of the filler wire X having contacted the molten pool WY (to-be-welded site | part) of the metal plate W1, it requests | requires after a contact from a preliminary heating state by switching an energized state as mentioned above. It is possible to shift to the original heated state at an accurate timing.

  Further, in the present embodiment, the filler wire X is irradiated with the laser beam so that the end of the filler wire X comes into contact with the molten pool WY formed in the irradiated portion L of the laser beam LB and storing the molten metal Wy. The filler wire X is supplied from a position behind the irradiated portion L, and is energized and heated so as to melt with the heat of the molten pool WY when the filler wire X comes into contact with the molten pool WY. That is, the filler wire X is melted without being irradiated with the laser beam LB. In this case, if the temperature of the filler wire X is low, the filler wire X may not be melted well. However, this problem can be satisfactorily solved by energizing before the filler wire X contacts the molten pool WY as in the present embodiment.

(Other embodiments)
The embodiment described above is one aspect for carrying out the present invention, and can be realized in various aspects other than this.

  For example, in the said embodiment, when the contact to the molten pool WY of the edge part of the filler wire X was detected by the control unit 100 based on the image detected by the imaging device 110, it comprised so that an energization state might be switched. However, you may comprise as follows. That is, a timer (time measuring means) for measuring the time after outputting the welding start signal to the control unit 100 is provided, and when the time measured by the timer reaches a predetermined time (supply start in claims) A switch switching control signal may be output to the filler heating power supply 31 at a later predetermined time). The predetermined time is set based on, for example, the distance between the position of the end of the filler wire X before the start of supply and the planned contact position of the metal plate W1 with the molten pool W1 and the supply speed of the filler wire X. Is possible. Also by this, it is possible to shift from the preliminary heating state to the original heating state required after the contact with almost accurate timing. In addition, the same effects as those of the above-described embodiment can be obtained with a simple configuration without providing the imaging device 110 and the like.

  Moreover, in the said embodiment, the filler wire X is more than a laser beam irradiation site | part so that the edge part may contact the molten pool WY formed in the site | part to be welded by the laser beam LB, and the molten metal Wy is stored. Although the case where the filler wire X is supplied to the rear position and is melted by the heat of the molten pool when contacting the molten pool has been described, the present invention is not limited to the rear side of the laser beam irradiated portion. The present invention can also be applied to the case where the filler wire is melted by supplying the filler wire from other directions and irradiating the end portion of the filler wire with laser light. That is, by heating the filler wire in advance, the melting load due to the laser light is reduced and the meltability of the filler wire is improved.

  The present invention makes it possible to melt the filler wire satisfactorily from the start of welding and stabilize the laser welding state when laser welding is performed while supplying filler wires to the welded parts of a plurality of metal members. Provided is a filler wire supply device and a supply method. Therefore, in addition to the automobile industry, it may be widely used in industries that require welding of metal members.

DESCRIPTION OF SYMBOLS 1 Laser welding apparatus 3 Filler wire supply apparatus 5 Clamp (3rd electrode)
6 Filler wire heating device (heating means)
11 Nozzle 31 Filler wire heating power supply device (energization means)
40 Filler wire heating head 51A First roller (first electrode)
51B Second roller (second electrode)
100 Control unit (contact detection means)
110 Imaging device (contact detection means)
L Laser beam irradiated part LB Laser light R Welding path X Filler wire W1 Upper metal plate W2 Lower metal plate WK Molten hole WY Molten pool Wy Molten metal Z Gap

Claims (7)

A filler wire supply device that supplies a filler wire so as to follow a state in which an end portion is in contact with a welded portion by a laser beam that moves relative to a plurality of metal members along a predetermined welding path,
Having heating means for heating by energizing the filler wire;
The heating means includes at least one of a first electrode that is in contact with a portion near the end of the filler wire, a second electrode that is in contact with the filler wire at a position spaced from the first electrode, and the metal member. When the supply of the third electrode in contact with the filler wire and the filler wire starts, the first electrode and the second electrode are energized via the filler wire, and after the predetermined time after the supply starts, the first electrode An apparatus for supplying filler wire in laser welding, comprising: an energizing means for energizing through one of a filler wire and a metal member between one electrode of the electrode and the second electrode and the third electrode. In the filler wire supply apparatus in laser welding according to claim 1,
A contact detection means for detecting that the end of the wire is in contact with the welded part after the supply of the filler wire is started;
The filler wire supply apparatus in laser welding, wherein the predetermined time after the start of supply is when contact of the end is detected by the contact detection means. In the filler wire supply apparatus in laser welding according to claim 1,
Comprising a time measuring means for measuring an elapsed time from the start of supply of the filler wire,
The predetermined time after the start of supply is a time when the time measured by the time measuring means has reached a predetermined time. In the filler wire supply apparatus in the laser welding according to any one of claims 1 to 3,
The filler wire supply means is arranged so that the filler wire is placed behind the laser beam irradiated site so that the end of the filler wire is in contact with a molten pool formed at the site to be welded by the laser beam and storing molten metal. Is supplied at the position of
The said heating means heats the said filler wire so that it may fuse | melt with the heat of this molten pool when it contacts a molten pool, The filler wire supply apparatus in laser welding characterized by the above-mentioned. In the filler wire supply device in laser welding according to any one of claims 1 to 4,
Each of the first electrode and the second electrode is constituted by a roller that movably supports the filler wire, and a filler wire supply apparatus in laser welding. In the filler wire supply device in laser welding according to claim 5,
Each of the rollers constituting the first electrode and the second electrode is composed of a pair of upper and lower rollers, and is configured to be able to assist the transfer of the filler wire supplied from the upstream side by being driven by a driving means. And
And the roller which comprises the said 1st electrode is driven so that it may become a supply speed quicker than the roller which comprises the said 2nd electrode, The filler wire supply apparatus in laser welding characterized by the above-mentioned. A filler wire supply method for supplying a filler wire so as to follow a state in which an end portion is in contact with a welded portion by a laser beam that moves relative to a plurality of metal members along a predetermined welding path,
Having a heating step of heating by energizing the filler wire;
The heating step includes a first electrode that contacts a portion near the end of the filler wire and a second electrode that contacts a position separated from the first electrode in the filler wire at the start of supply of the filler wire. A third electrode in contact with at least one of the first electrode and the second electrode and the metal member after a predetermined time after the start of supply by energizing the filler wire therebetween A filler wire supply device in laser welding, wherein electricity is passed through a filler wire and a metal member.