JP2012066284A - Spot welding method and spot welding device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To sufficiently grow the nuggets on the contact interface of workpieces with each other when applying a spot welding to a stacked body formed by stacking a plurality of workpieces.SOLUTION: The welding gun 14 composing a spot welding device is provided with the lower and upper tips 32 and 38 which serve as welding tips, and pressing rods 46a and 46b which serve as pressing members. The upper tip 38 and the pressing rods 46a and 46b among the above elements press the stacked body 48a which is to be welded, by the pressurizing forces F1, F2 and F3, respectively from the side of a metallic plate 54a which is the outermost member of the stacked body 48a, and the lower tip 32 presses the stacked body 48a from the side of the metallic plate 50a by a pressurizing force F4. The total of pressurizing forces F1, F2 and F3 is controlled to balance with the force F4, and in such a state, an electric current is conducted from the upper tip 38 to the lower tip 32.

Description

  The present invention relates to a spot welding method and apparatus for performing spot welding on a laminate formed by laminating a plurality of workpieces.

  FIG. 23 is a front view of a main part schematically showing a case where high resistance workpieces 1 and 2 made of so-called high-tensile steel and having a large thickness and thus high electrical resistance are joined by spot welding. In this case, after the laminated body 3 is formed by laminating the two high resistance workpieces 1 and 2, the laminated body 3 is sandwiched and pressed between the first welding tip 4 and the second welding tip 5. The Further, energization is performed between the first welding tip 4 and the second welding tip 5, and accordingly, a portion near the contact surface between the high resistance workpieces 1, 2 is heated and becomes a melting part 6. Thereafter, the melting part 6 is solidified and becomes a solid phase called a nugget.

  Here, since the high resistance workpieces 1 and 2 have large electric resistance, Joule heat generated near the contact surface during energization is large. For this reason, as shown in FIG. 24, the melted portion 6 grows large in a relatively short time, and as a result, the melted portion 6 is likely to be scattered (sputtering is likely to occur). Therefore, when joining the high resistance workpieces 1 and 2 by spot welding, it is necessary to control the welding current with high accuracy in order to avoid spattering, but such control is not easy. This also applies to the case of high-tensile steel with a small thickness.

  Moreover, when joining 3 or more workpiece | work, the material and thickness of a workpiece | work are not necessarily the same, For example, as shown in FIG. 25, the thickness of the outermost workpiece | work (low resistance workpiece | work 7) is shown. It can be minimal. The laminated body 8 in FIG. 25 is formed by further laminating a low resistance work 7 made of mild steel and having a small electric resistance on the high resistance works 1 and 2 shown in FIGS. 23 and 24. .

  When spot welding is performed on this laminate 8, Joule heat generated near the contact surface between the high resistance workpieces 1 and 2 rather than Joule heat generated near the contact surface between the low resistance workpiece 7 and the high resistance workpiece 2. Is bigger. This is because the contact resistance is larger in the vicinity of the latter contact surface.

  Accordingly, in the laminated body 8, first, the melting part 9 is formed on the contact surface between the high resistance workpieces 1 and 2. In some cases, as shown in FIG. 26, the melted portion 9 may grow greatly before the melted portion is formed on the contact surface between the low resistance work 7 and the high resistance work 2. If energization is continued to form a melted part on the contact surface between the low resistance workpiece 7 and the high resistance workpiece 2 in such a state, there is a concern that spatter will occur from the contact surface between the high resistance workpieces 1 and 2.

  However, when energization is stopped, a sufficiently large melted part and consequently no nugget is formed on the contact surface between the low resistance work 7 and the high resistance work 2, so that the bonding strength between the low resistance work 7 and the high resistance work 2 is ensured. Difficult to do.

  Therefore, in Patent Document 1, when performing spot welding on such a laminated body, the applicant of the present application makes the pressure of the first welding tip that contacts the low-resistance workpiece smaller than that of the second welding tip. Propose to set. In this case, the contact pressure of the low resistance workpiece with respect to the high resistance workpiece is reduced, and as a result, the contact resistance between the contact surfaces of the low resistance workpiece and the high resistance workpiece is increased. Thereby, sufficient Joule heat is generated on the contact surface. Therefore, it becomes possible to grow the nugget between the low resistance work and the high resistance work to a size substantially the same as the nugget formed between the high resistance work. Obtainable.

Japanese Patent No. 3894545

  The present invention has been made in connection with the technique described in Patent Document 1, and can sufficiently grow nuggets in the vicinity of the contact surface between the workpieces in the laminate, and further eliminates the concern that spatter will occur. It is an object of the present invention to provide a spot welding method and an apparatus for the same.

In order to achieve the above object, the present invention is a spot welding method for performing spot welding on a laminate formed by laminating a plurality of workpieces,
The laminated body is sandwiched between the first welding tip and the second welding tip, and a pressure member is brought into contact with the outermost work that is located on the outermost side of the laminated body and is in contact with the first welding tip. , The step of pressurizing the laminate from the outermost work side by the pressurizing member;
Maintaining the pressure applied by the pressure member and energizing between the first welding tip and the second welding tip;
It is characterized by having.

  In this case, the total pressing force of the first welding tip and the pressing member is balanced with the pressing force of the second welding tip, so that the pressing force of the first welding tip is smaller than that of the second welding tip. Therefore, between the first welding tip side and the second welding tip that is substantially opposite to the first welding tip, the range of action of the applied pressure increases from the first welding tip side toward the second welding tip. Distributed. For this reason, the force which acts on the contact surface of the outermost workpiece | work which the 1st welding tip contact | abutted and the workpiece | work adjacent to it becomes small compared with the force which acts on the contact surface of the remaining workpieces.

  As a result of this distribution, the contact area between the outermost workpiece and the workpiece adjacent to it is smaller than the contact area between the remaining workpieces. Therefore, it is possible to increase the contact resistance of the contact surface between the outermost workpiece and the workpiece adjacent thereto, thereby increasing the amount of heat generated based on Joule heat. Therefore, it is possible to greatly grow the nugget generated on the contact surface, and eventually it is possible to secure the bonding strength between the outermost workpiece and the workpiece adjacent thereto.

  In addition, since the metal plate is pressed by the pressing member, the outermost work is prevented from being separated from the work adjacent thereto. Therefore, it is possible to prevent the softened melted portion from being scattered as a spatter from the separated portion between the outermost workpiece and the workpiece adjacent thereto.

  The pressurizing member is composed of an auxiliary electrode having a polarity opposite to that of the first welding tip, and when the energization is performed, a branching current from the first welding tip to the auxiliary electrode, or from the auxiliary electrode to the first welding. Any of the branch currents going to the chip may be generated.

  In this case, the current flowing from the first welding tip toward the auxiliary electrode or the current flowing in the opposite direction flows through the inside of the outermost workpiece, so that the current contacts the outermost workpiece with the workpiece adjacent thereto. The surface is fully heated. As a result, a sufficiently large nugget grows on the contact surface, so that a bonded portion with even better bonding strength can be obtained.

  In addition, another auxiliary electrode having a polarity opposite to that of the second welding tip is provided on the second welding tip side, and branching from the first welding tip toward the auxiliary electrode (auxiliary electrode on the first welding tip side). After erasing either the current or the branch current from the auxiliary electrode toward the first welding tip, the branch current from the other auxiliary electrode (auxiliary electrode on the second welding tip side) toward the second welding tip Alternatively, any one of the branch currents from the second welding tip toward the other auxiliary electrode may be allowed to flow.

  In this case, the nugget can be sufficiently grown on the contact surface between the outermost workpiece with which the second welding tip abuts and the workpiece adjacent thereto.

Further, the present invention is a spot welding apparatus for performing spot welding on a laminate formed by laminating a plurality of workpieces,
A first welding tip and a second welding tip for sandwiching the laminate,
A pressing member for contacting a portion of the outermost work positioned on the outermost side of the layered body different from a portion contacted by the first welding tip, and pressurizing the laminated body from the outermost work side; ,
A pressurizing mechanism for generating a pressurizing force on the pressurizing member;
It is characterized by having.

  By setting it as such a structure, the applied pressure with respect to the laminated body by a 1st welding tip and a 2nd welding tip can be distributed so that an action range may become large toward the 2nd welding tip from the 1st welding tip side. it can. As a result, it is possible to increase the contact resistance of the contact surface between the outermost workpiece with which the first welding tip abuts and the workpiece adjacent thereto, and the contact surface is sufficiently heated to obtain a nugget of an appropriate size. Can grow. Thereby, the joining strength of the outermost workpiece | work and the workpiece | work adjacent to this can be enlarged.

  In addition, when supporting the welding gun provided with the 1st welding tip and the 2nd welding tip with a robot, it is preferable to provide the said pressurization mechanism in a welding gun. In this case, since the reaction force from the laminated body can be absorbed by the welding gun, the reaction force is prevented from reaching the robot. Therefore, it is not particularly necessary to use a robot having high rigidity. In other words, since a small robot can be adopted, the capital investment can be reduced.

  Further, when the pressing member is constituted by an auxiliary electrode having a polarity opposite to that of the first welding tip and the energization is performed, a branching current from the first welding tip to the auxiliary electrode, or from the auxiliary electrode to the first electrode. Any of the branch currents directed to the welding tip may be generated. As described above, in this case, the contact surface between the metal plate and the workpiece adjacent thereto is sufficiently heated by the current flowing from the first welding tip toward the auxiliary electrode or the current flowing in the opposite direction. This is because a nugget having a sufficiently large size can be grown on the surface, and a bonded portion with even higher bonding strength can be obtained.

  Furthermore, another auxiliary electrode having a polarity opposite to that of the second welding tip may be provided on the second welding tip side. In this case, after erasing either the branch current from the first welding tip toward the auxiliary electrode (auxiliary electrode on the first welding tip side) or the branch current from the auxiliary electrode toward the first welding tip. Either a branch current from the other auxiliary electrode (second electrode on the second welding tip) toward the second welding tip or a branch current from the second welding tip toward the other auxiliary electrode is allowed to flow. That's fine.

  Thereby, the nugget can be sufficiently grown on the contact surface between the outermost workpiece with which the second welding tip abuts and the workpiece adjacent thereto.

  According to the present invention, in addition to sandwiching the laminated body between the first welding tip and the second welding tip, the workpiece arranged at the outermost part of the laminated body is pressurized with the pressure member, and spot welding is performed in this state. Like to do. For this reason, the pressurizing force with respect to the laminated body is distributed so that the action range becomes larger from the first welding tip toward the second welding tip.

  As a result of the distribution of the applied pressure in this way, the contact area of the contact surface between the outermost workpiece and the workpiece adjacent thereto decreases, and accordingly, the contact resistance of the contact surface increases. Therefore, since Joule heat that can sufficiently heat the contact surface is generated, a sufficiently large nugget can be grown on the contact surface. Thereby, the outermost workpiece | work and the workpiece | work adjacent to this are joined with sufficient joining strength. In other words, sufficient bonding strength can be ensured between the outermost workpiece and the workpiece adjacent thereto.

  The pressurizing member may be configured as an auxiliary electrode, and a current from the first welding tip (or second welding tip) toward the auxiliary electrode or a current in the opposite direction may be allowed to flow.

  According to the present invention, in addition to sandwiching the laminated body between the first welding tip and the second welding tip, the workpiece arranged at the outermost part of the laminated body is pressurized with the pressure member, and spot welding is performed in this state. Like to do. For this reason, the pressurizing force with respect to the laminated body is distributed so that the action range becomes larger from the first welding tip toward the second welding tip.

  As a result of the distribution of the applied pressure in this way, the contact area at the contact surface between the outermost workpiece and the workpiece adjacent thereto decreases, and accordingly, the contact resistance near the contact surface increases. Therefore, since Joule heat that can sufficiently heat the vicinity of the contact surface is generated, a sufficiently large nugget grows in the vicinity of the contact surface. Thereby, the outermost workpiece | work and the workpiece | work adjacent to this can be joined with sufficient joining strength.

It is a principal part enlarged view of the spot welding apparatus which concerns on 1st Embodiment of this invention. It is a principal part schematic front view which shows the state which clamped the laminated body which is welding object with the lower chip | tip, the upper chip | tip, and the rod for pressurization (pressurization member). It is the front schematic diagram and graph which show an example of the state by which distribution of appropriate surface pressure was formed between the workpiece | work located in the uppermost part of a laminated body, and the workpiece | work just under it. It is a front schematic diagram which shows the state which clamped the said laminated body only with the lower chip | tip and the upper chip | tip. It is a longitudinal cross-sectional schematic diagram which shows the state which started electricity supply from FIG. 2 and sent the electric current which flows from an upper chip | tip to a lower chip | tip. It is a principal part schematic front view which shows the state which clamped the laminated body different from FIG. 2 with the lower chip | tip, the upper chip | tip, and the pressurizing rod (pressurizing member). It is a principal part schematic front view which shows the state which clamped the laminated body different from FIG.2 and FIG.6 with the lower chip | tip, the upper chip | tip, and the rod for pressurization (pressurization member). It is a principal part schematic front view which shows the state which clamped the laminated body with the upper chip | tip (1st electrode chip | tip), lower chip | tip (2nd electrode chip | tip), and auxiliary electrode which comprise the spot welding apparatus which concerns on 2nd Embodiment of this invention. is there. It is a longitudinal cross-sectional schematic diagram which shows the state which started electricity supply from FIG. 8 and sent the electric current which flows from an upper chip | tip to a lower chip | tip. It is a longitudinal cross-sectional schematic diagram which shows the state which continued electricity supply from FIG. It is a longitudinal cross-sectional schematic diagram which shows the state which continued energization from the upper chip | tip to the lower chip | tip, while separating only an auxiliary electrode from a laminated body. FIG. 12 is a schematic longitudinal sectional view showing a state where the upper chip is separated from the laminated body and the energization (spot welding) is completed following FIG. 11. FIG. 9 is a schematic front view of a main part showing a state where a laminate different from FIG. 8 is sandwiched between a lower chip, an upper chip, and an auxiliary electrode and energization is started. It is a longitudinal cross-sectional schematic diagram which shows the state which continued energization from the upper chip | tip while cut | disconnecting electrical connection with the auxiliary electrode and the negative electrode of a power supply. It is a longitudinal cross-sectional schematic diagram which shows the state which complete | finished electricity supply (spot welding). It is a principal part schematic front view which shows the state which clamped the laminated body different from FIG.8 and FIG.13 with a lower chip | tip, an upper chip | tip, and an auxiliary electrode, and started electricity supply. It is a longitudinal cross-sectional schematic diagram which shows the state which complete | finished electricity supply (spot welding). FIG. 14 is a schematic front view of a main part showing a state in which energization is started by sandwiching a laminated body different from FIGS. 8 and 13 by a lower chip, an upper chip, and an auxiliary electrode on the upper chip side. The electrical connection between the auxiliary electrode on the upper chip side and the negative electrode of the power supply is cut, while the state where the auxiliary electrode on the lower chip side is brought into contact with the workpiece while energization from the upper chip to the lower chip is continued. It is a longitudinal cross-sectional schematic diagram. It is a longitudinal cross-sectional schematic diagram which shows the state which continued the electricity supply from the upper chip | tip to the lower chip | tip, while cut | disconnecting the electrical connection of the said auxiliary electrode by the lower chip | tip side and the negative electrode of a power supply. Contrary to FIG. 9, FIG. 10 is a schematic vertical cross-sectional view showing a state in which a current flowing from the lower chip and the auxiliary electrode toward the upper chip is passed. It is a longitudinal cross-sectional schematic diagram which shows the state through which the electric current which goes to an auxiliary electrode from the upper chip | tip flows into the workpiece | work located in the uppermost part of a laminated body, and the workpiece | work directly under it. It is a longitudinal cross-sectional schematic diagram which shows the state which sent the electric current which went to a lower chip | tip from the upper chip | tip in the general spot welding which clamps a laminated body only with a lower chip | tip and an upper chip | tip. It is a longitudinal cross-sectional schematic diagram which shows the state which the fusion | melting part grew from FIG. FIG. 24 is a schematic vertical cross-sectional view showing a state in which a laminated body different from FIG. 23 is sandwiched between only a lower chip and an upper chip, and a current flowing from the upper chip to the lower chip is passed. It is a longitudinal cross-sectional schematic diagram which shows the state which the fusion | melting part grew from FIG.

  DESCRIPTION OF EMBODIMENTS Hereinafter, a spot welding method according to the present invention will be described in detail with reference to the accompanying drawings by giving preferred embodiments in relation to a spot welding apparatus for carrying out the spot welding method.

  FIG. 1 is an enlarged view of a main part of a spot welding apparatus 10 according to the first embodiment. The spot welding apparatus 10 includes a robot (not shown) having an arm, and a welding gun 14 supported by a wrist portion 12 constituting the arm.

  In this case, the welding gun 14 is a so-called C-type having a substantially C-shaped fixed arm 30 disposed below the gun body 24. A lower tip 32 as a second welding tip is provided at the lower end of the fixed arm 30 so as to face the gun body 24, and the lower tip 32 extends toward the gun body 24.

  The gun body 24 accommodates a ball screw mechanism (not shown). The ball screw of this ball screw mechanism is for displacing the connecting rod 34 protruding from the gun body 24 and extending toward the lower tip 32 in the vertical direction (arrow Y2 direction or arrow Y1 direction) in FIG. is there. The ball screw rotates under the action of a servo motor (not shown) constituting the ball screw mechanism.

  An upper tip 38 as a first welding tip is provided at the distal end portion of the connecting rod 34 via the stay 36 so as to face the lower tip 32. Further, two cylinder mechanisms 42 a and 42 b are supported on the stay 36 via the bridge member 40. The pressure rods 46a and 46b as pressure members protrude from the cylinder tubes 44a and 44b constituting the cylinder mechanisms 42a and 42b so as to extend in parallel with the upper tip 38.

  The laminated body 48a to be welded will be described briefly. In this case, the laminated body 48a is configured by laminating three metal plates 50a, 52a, 54a in this order from below. The thickness of the metal plates 50a and 52a is set to D1 (for example, about 1 mm to about 2 mm), and the thickness of the metal plate 54a is smaller than D1 (for example, about 0.5 mm to about 0). .7 mm). That is, the metal plates 50a and 52a have the same thickness, and the metal plate 54a is thinner than the metal plates 50a and 52a. That is, the thickness of the metal plate 54a is the smallest among the three metal plates 50a, 52a, 54a constituting the laminated body 48a.

  The metal plates 50a and 52a are, for example, high-resistance work made of so-called high-tensile steel JAC590, JAC780 or JAC980 (all high-performance high-tensile steel plates specified in the Japan Iron and Steel Federation standard), and the metal plate 54a is, for example, In other words, it is a low-resistance work made of so-called mild steel JAC270 (a steel plate for high-performance drawing as defined in the Japan Iron and Steel Federation standard). The metal plates 50a and 52a may be the same metal species or different metal species.

  The lower chip 32 and the upper chip 38 sandwich the laminated body 48a to be welded between the lower chip 32 and the upper chip 38 and energize the laminated body 48a. The lower chip 32 is electrically connected to the negative electrode of the power source 56, while the upper chip 38 is electrically connected to the positive electrode of the power source 56. For this reason, in the first embodiment, a current flows from the upper chip 38 toward the lower chip 32.

  As will be described later, the separation distances Z1 and Z2 between the upper tip 38 and the pressure rods 46a and 46b are set so that an appropriate surface pressure distribution can be obtained between the metal plate 54a and the metal plate 52a immediately below the metal plate 54a. Is done.

  In the above configuration, the servo motor, the cylinder mechanisms 42a and 42b, and the power source 56 constituting the ball screw mechanism are electrically connected to a gun controller 58 as a control means. That is, the operation, energization / energization of these servo motors, cylinder mechanisms 42a, 42b, and power source 56 is controlled by the gun controller 58.

  The spot welding apparatus 10 according to the first embodiment is basically configured as described above. Next, the function and effect will be described in relation to the spot welding method according to the first embodiment. .

  When spot welding is performed on the laminated body 48a, in other words, when the metal plates 50a and 52a are joined together and the metal plates 52a and 54a are joined together, the robot first moves the lower chip 32 and the upper chip 32 together. The wrist 12, that is, the welding gun 14 is moved so that the laminated body 48 a is disposed between the tips 38.

  After the gun body 24 is lowered to a predetermined position, the servo motor constituting the ball screw mechanism is energized under the action of the gun controller 58, and the ball screw starts to rotate accordingly. As a result, the upper tip 38 and the pressure rods 46a and 46b descend in the direction of the arrow Y1 so as to be closer to the stacked body 48a. As a result, the stacked body 48 a is sandwiched between the lower chip 32 and the upper chip 38.

  On the other hand, the gun controller 58 urges the cylinder mechanisms 42a and 42b. Accordingly, the pressure rods 46a and 46b further protrude in the direction of the arrow Y1, and the pressure rods 46a and 46b are simultaneously or before and after the stacked body 48a is sandwiched between the lower chip 32 and the upper chip 38. It contacts the metal plate 54a. FIG. 2 shows a schematic longitudinal sectional view at this time.

  Here, the separation distances Z1 and Z2 between the upper tip 38 and the pressure rods 46a and 46b are pressed by the upper tip 38 against the contact surface between the metal plate 54a and the metal plate 52a, as shown in FIG. It is set so that the surface pressure becomes maximum at the location and the next highest surface pressure is obtained at the location where the pressure rods 46a and 46b are pressed. Preferably, Z1 = Z2.

  In other words, the contact surface is formed with a portion where the surface pressure is smaller than the surface pressure due to the pressure of the upper tip 38 and the surface pressure due to the pressure of the pressure rods 46a and 46b. As a result, a pressure distribution as shown in FIG. 2 is formed. Hereinafter, this distribution will be described in detail.

  The gun controller 58 adjusts the ball screw so that the total pressing force (F1 + F2 + F3) of the upper tip 38 and the pressure rods 46a, 46b against the metal plate 54a is balanced with the pressing force (F4) of the lower tip 32 against the metal plate 50a. The rotational biasing force of the servo motor that rotates the ball screw of the mechanism and the propulsive force of the cylinder mechanisms 42a and 42b are controlled. By this control, the pressure force (F1 + F2 + F3) acting along the arrow Y1 direction on the stacked body 48a and the pressure force (F4) acting along the arrow Y2 direction become substantially equal. It is preferable that F2 = F3.

  That is, at this time, F1 <F4 holds. Therefore, the force that the multilayer body 48a receives from the lower chip 32 and the upper chip 38 is distributed so that the range of action increases (becomes larger) from the upper chip 38 toward the lower chip 32, as schematically shown in FIG. To do. For this reason, the force acting on the contact surfaces of the metal plates 52a and 54a is smaller than the force acting on the contact surfaces of the metal plates 50a and 52a. In addition, when the separation distances Z1 and Z2 are excessively small, a portion where the surface pressure is smaller than the surface pressure by pressing the upper tip 38 and the surface pressure by pressing the pressure rods 46a and 46b is not formed. Such a distribution is difficult to be formed.

  FIG. 4 schematically shows the distribution of the force that the laminate 48a receives from the lower chip 32 and the upper chip 38 when F1 = F4 without using the pressure rods 46a and 46b. As can be appreciated from FIG. 4, in this case, the force is even from the upper tip 38 to the lower tip 32. In other words, the force acting on the contact surfaces of the metal plates 52a and 54a is equal to the force acting on the contact surfaces of the metal plates 50a and 52a.

  In FIG.2 and FIG.4, the range of the force which acts on the contact surface of the metal plates 52a and 54a is shown by the thick solid line. As can be seen by comparing FIGS. 2 and 4, the range in which the force acts is narrower when F1 <F4 than when F1 = F4. This means that when F1 <F4, the range in which the metal plate 54a is pressed against the metal plate 52a is narrower than when F1 = F4, in other words, the contact area is small. To do.

  Here, the pressure from the upper chip 38 to the lower chip 32 is distributed in this way, and the contact area of the metal plate 54a with the metal plate 52a is reduced, so that the reaction from the stacked body 48a toward the upper chip 38 occurs. Power is generated. In the first embodiment, this reaction force is received by the pressure rods 46a and 46b.

  As described above, the cylinder mechanisms 42 a and 42 b including the pressure rods 46 a and 46 b are supported via the bridge member 40 with respect to the connecting rod 34 connected to the ball screw mechanism accommodated in the gun body 24. . Therefore, the reaction force received by the pressure rods 46a and 46b is eventually absorbed by the gun body 24 (welding gun 14).

  Therefore, in this case, reaction force from the stacked body 48a is prevented from acting on the robot. For this reason, it is not necessary to employ a robot having high rigidity. In other words, a small robot can be adopted, and as a result, capital investment can be reduced.

  Next, the gun controller 58 issues a control signal for starting energization to the power source 56. Thereby, as shown in FIG. 2 (and FIG. 4), the current i starts to flow in the direction from the upper chip 38 toward the lower chip 32. This is because the upper chip 38 and the lower chip 32 are connected to the positive electrode and the negative electrode of the power source 56 as described above. And between Joule heat based on electric current i, between metal plates 50a and 52a and between metal plates 52a and 54a is heated, respectively.

  Here, as described above, the contact area between the metal plate 54a and the metal plate 52a shown in FIG. 2 is smaller than the contact area between the metal plate 54a and the metal plate 52a shown in FIG. For this reason, the contact resistance and current density at the contact surfaces of the metal plates 52a and 54a are compared with the case shown in FIG. 2 in comparison with the case shown in FIG. 4, in other words, when F1 <F4. Is larger than when F1 = F4. That is, when F1 <F4, the amount of generated Joule heat, in other words, the amount of heat generation, is larger than when F1 = F4. Therefore, when F1 <F4, as shown in FIG. 5, the heating region 60 generated on the contact surface of the metal plates 50a and 52a and the heating region 62 generated on the contact surface of the metal plates 52a and 54a are substantially equal. Grow to the size of.

  The contact surfaces of the metal plates 50a and 52a and the contact surfaces of the metal plates 52a and 54a are heated by the heating regions 60 and 62, and the temperature rises sufficiently to start melting. As a result, the formed melted portion is cooled and solidified. As a result, nuggets 64 and 66 are formed between the metal plates 50a and 52a and between the metal plates 52a and 54a, respectively. In FIG. 5, the nuggets 64 and 66 are shown for ease of understanding. However, during energization, they exist as melted portions that are in a liquid phase. The same applies to the subsequent drawings.

  As described above, the heating region 60 on the contact surface of the metal plates 50a and 52a and the heating region 62 on the contact surface of the metal plates 52a and 54a are approximately the same size. Accordingly, the nuggets 64 and 66 are also approximately the same size.

  While the melting part is formed, the metal plate 54a is pressed to the metal plate 52a side by the pressure rods 46a and 46b. This pressing suppresses the low-rigidity metal plate 54a from being warped with energization (heating), that is, being separated from the metal plate 52a. For this reason, it is possible to prevent the softened melted portion from being scattered as a spatter from the space between the metal plate 54a and the metal plate 52a.

  After a predetermined time has elapsed and the melted portion has sufficiently grown, the energization is stopped and the upper chip 38 is separated from the metal plate 54a. Alternatively, the upper chip 38 and the lower chip 32 may be electrically insulated by separating the upper chip 38 from the metal plate 54a.

  All the operations described above from the start to the end of spot welding are performed under the control action of the gun controller 58.

  As the energization is stopped in this manner, the heat generation of the metal plates 50a, 52a, and 54a is also terminated. As time elapses, the melted portions are cooled and solidified to form nuggets 64 and 66, and a joined product in which the metal plates 50a and 52a and the metal plates 52a and 54a are joined to each other through the nuggets 64 and 66 is obtained. To.

  In this bonded product, the bonding strength between the metal plates 52a and 54a is excellent as well as the bonding strength between the metal plates 50a and 52a. This is because the nugget 66 between the metal plates 52a and 54a is sufficiently grown as a sufficient Joule heat is generated on the contact surfaces of the metal plates 52a and 54a as described above.

  As described above, according to the first embodiment, while avoiding the generation of spatter, between the metal plates 52a and 54a, the size of the nugget 64 between the metal plates 50a and 52a is approximately the same. The nugget 66 can be grown, whereby a molded product having excellent bonding strength between the metal plates 52a and 54a can be obtained.

  In the first embodiment, the nugget 66 between the metal plates 52a and 54a can be increased as the applied pressures F2 and F3 by the pressure rods 46a and 46b are increased. However, if the applied pressures F2 and F3 are increased to some extent, The size of 66 tends to saturate. In other words, even if the applied pressures F2 and F3 are excessively increased, it is difficult to grow the nugget 66 beyond a certain size. Further, if the applied pressures F2 and F3 are excessively increased, the applied pressure F1 needs to be excessively reduced in order to balance the applied pressure F4 with the sum of the applied pressures F1, F2 and F3. For this reason, the nugget 64 between the metal plates 50a and 52a becomes small.

  Therefore, the difference between the pressurizing force F1 by the upper tip 38 and the pressurizing forces F2 and F3 by the pressurizing rods 46a and 46b is preferably set so that the nuggets 64 and 66 can be made as large as possible.

  In the spot welding apparatus 10 shown in FIG. 1, the cylinder mechanisms 42 a and 42 b are supported by the connecting rod 34, but the cylinder mechanisms 42 a and 42 b may be supported by the gun body 24, You may make it support with the fixed arm 30. FIG.

  In any case, various pressure applying means such as a spring coil and a servo motor can be employed instead of the cylinder mechanisms 42a and 42b.

  Further, the pressurizing member may have an annular shape surrounding the upper chip 38.

  Furthermore, the combination of the materials of the metal plates 50a, 52a, and 54a is not particularly limited to the steel material described above, and any combination that allows spot welding is acceptable. For example, a combination in which all of the metal plates 50a, 52a, 54a are mild steel may be used, or a combination in which only the metal plate 50a is high-tensile steel and the metal plates 52a, 54a are mild steel.

  Further, the object to be welded is not limited to the laminate 48a in which the thickness of the uppermost metal plate 54a is smaller than that of the metal plates 50a and 52a, but the metal having the smallest thickness as shown in FIG. The laminated body 48b formed so that the board 52b may be pinched | interposed with the metal plates 50b and 54b may be sufficient. Examples of the combination of materials in this case include a combination in which the metal plate 50b is made of high-tensile steel and the metal plates 52b and 54b are made of mild steel, but it is of course not limited to this.

  Of course, it may be a laminate in which the thickness of the metal plate located at the center is the maximum, or a laminate in which the thickness of the metal plate located at the bottom is smaller than the other two metal plates. Also good.

  The number of metal plates is not particularly limited to the above three. For example, as shown in FIG. 7, a laminate 48c in which a metal plate 52c made of high-tensile steel is laminated on a metal plate 50c made of high-tensile steel may be used.

  The pressure member may be an auxiliary electrode. Hereinafter, this case will be described as a second embodiment. The same components as those shown in FIGS. 1 to 7 are denoted by the same reference numerals, and detailed description thereof is omitted.

  FIG. 8 is an enlarged partial cross-sectional perspective view of a main part of the spot welding apparatus according to the second embodiment. A welding gun (not shown) constituting the spot welding apparatus is provided on the wrist 12 (see FIG. 1) of the robot (not shown), similarly to the welding gun constituting the spot welding apparatus according to the first embodiment. It has a lower tip 32 as a welding tip and an upper tip 38 as a first welding tip, and further has auxiliary electrodes 68a and 68b formed in a rod shape like the pressure rods 46a and 46b. In the second embodiment, it is assumed that a current flows from the upper chip 38 toward the lower chip 32.

  In this case, the gun body 24 that supports the upper tip 38 is provided with a displacement mechanism, such as a ball screw mechanism or a cylinder mechanism, for moving the auxiliary electrodes 68a and 68b toward or away from the laminated body 48a. By this displacement mechanism, the auxiliary electrodes 68a and 68b can approach or separate from the stacked body 48a separately from the upper chip 38. In the second embodiment, the displacement mechanism is preferably provided on the welding gun side.

  In the second embodiment, the upper chip 38 is electrically connected to the positive electrode of the power source 56, and the lower chip 32 and the auxiliary electrodes 68 a and 68 b are electrically connected to the negative electrode of the power source 56. As can be understood from this, both the upper chip 38 and the auxiliary electrodes 68a and 68b are in contact with the uppermost metal plate 54a in the stacked body 48a, but their polarities are opposite to each other. In the following drawings, when the upper chip 38 and the auxiliary electrodes 68a and 68b are electrically connected to generate the branch current i2, the polarities of the auxiliary electrodes 68a and 68b are shown in the figure, When the branch current i2 is not generated, the polarity of the auxiliary electrodes 68a and 68b is not shown.

  The separation distances Z3 and Z4 between the upper tip 38 and the auxiliary electrodes 68a and 68b are the surface pressure by the upper tip 38 and the surface pressure by the auxiliary electrodes 68a and 68b so that the applied pressure is distributed as in the first embodiment. In contrast, the surface pressure is set so as to be reduced (see FIG. 3). For this reason, the upper tip 38 and the auxiliary electrodes 68a and 68b are spaced apart to some extent. However, when the distances Z3 and Z4 between the upper tip 38 and the auxiliary electrodes 68a and 68b are excessively large, the upper tip 38 and the auxiliary electrodes 68a and 68b. And the branch current i2 (see FIG. 10) described later becomes difficult to flow.

  Therefore, the separation distances Z3 and Z4 can obtain the appropriate distribution of the surface pressure between the metal plate 54a and the metal plate 52a as described above, and the resistance between the upper chip 38 and the auxiliary electrodes 68a and 68b. , The distance at which the branch current i2 can flow at an appropriate current value is set.

  In the above configuration, the displacement mechanism and power source 56 (not shown) are electrically connected to the gun controller 58.

  The main part of the spot welding apparatus according to the second embodiment is basically configured as described above. Next, regarding the operational effects thereof, in relation to the spot welding method according to the second embodiment. explain.

  When spot welding is performed on the laminate 48a, the robot moves the welding gun so that the laminate 48a is disposed between the upper tip 38 and the lower tip 32, as in the first embodiment. Let Thereafter, the upper chip 38 and the lower chip 32 relatively approach each other, and as a result, the stacked body 48a is sandwiched between them.

  The auxiliary electrodes 68a and 68b are brought into contact with the metal plate 54a at the same time as or before and after the clamping, and are in a state shown as a schematic longitudinal sectional view in FIG. Of course, the displacement for bringing the auxiliary electrodes 68a and 68b into contact with the metal plate 54a is performed under the action of the displacement mechanism for displacing the auxiliary electrodes 68a and 68b.

  Also in this case, the gun controller 58 uses the pressurizing forces F2 and F3 of the auxiliary electrodes 68a and 68b to the metal plate 54a, and the sum of the pressurizing forces F2 and F3 and the pressurizing force F1 by the upper tip 38 (F1 + F2 + F3) is the lower tip. It is set so as to balance with the pressurizing force F4 by 32.

  In the second embodiment, as in the first embodiment, the difference between the pressurizing force F1 by the upper tip 38 and the pressurizing forces F2 and F3 by the auxiliary electrodes 68a and 68b is formed between the metal plates 50a and 52a. It is preferable that the nugget formed between the nugget and the metal plates 52a and 54a be set as large as possible.

  Next, energization is started. In the second embodiment, since each of the upper chip 38 and the lower chip 32 is connected to the positive electrode and the negative electrode of the power source 56, a current i1 flows from the upper chip 38 toward the lower chip 32 as shown in FIG. Due to the Joule heat based on the current i1, the space between the metal plates 50a and 52a and the space between the metal plates 52a and 54a are heated, and the heating regions 70 and 72 are formed.

  Here, the auxiliary electrodes 68a and 68b are also in contact with the metal plate 54a, and the polarity of the auxiliary electrodes 68a and 68b is negative. Therefore, the branch current i2 toward the auxiliary electrodes 68a and 68b starts from the upper chip 38 simultaneously with the current i1 described above.

  Thus, in the second embodiment, a branch current i2 that flows only through the metal plate 54a without flowing through the metal plates 50a and 52a is generated. As a result, the current value passing through the inside of the metal plate 54a becomes larger than in general spot welding using only the upper tip 38 and the lower tip 32.

  Therefore, in this case, a heating region 74 different from the heating region 72 is formed inside the metal plate 54a. The heating area 74 expands with time, and is integrated with the heating area 72 as shown in FIG.

  Heat is transmitted to the contact surfaces of the metal plates 52a and 54a from both of the heating regions 72 and 74 thus integrated. In addition, in this case, as in the first embodiment, the contact resistance of the contact surfaces of the metal plates 52a and 54a is larger than that of the contact surfaces of the metal plates 50a and 52a. For this reason, the contact surface sufficiently rises in temperature and starts to melt, and as a result, a nugget 76 is formed between the metal plates 52a and 54a.

  Here, it is possible to enlarge the heating region 74 as the ratio of the branch current i2 is increased. However, if the ratio of the branch current i2 is excessively increased, the current value of the current i1 is decreased. 72 becomes smaller. For this reason, while the size of the nugget 76 is saturated, the nugget 78 tends to be small. Therefore, it is preferable that the ratio of the branch current i2 is set so that the current i1 that allows the nugget 78 to grow sufficiently flows.

  The ratio between the current i1 and the branch current i2 can be adjusted by changing the distances Z3 and Z4 (see FIG. 8) between the upper tip 38 and the auxiliary electrodes 68a and 68b as described above. is there. A suitable ratio of the current i1 and the branch current i2 is, for example, 70:30.

  The melted portion, and thus the nugget 76 grows with the passage of time as long as energization is continued. Therefore, the nugget 76 can be sufficiently grown by continuing energization for a predetermined time.

  In this case, the current value of the current i1 flowing through the metal plates 50a and 52a is smaller than that of general spot welding. For this reason, it is avoided that the calorific value of the metal plates 50a and 52a becomes excessively large while the melted portion (nugget 76) between the metal plates 52a and 54a is growing large. Accordingly, concerns that spatter will occur are eliminated.

  During this time, a melted portion that becomes the nugget 78 is also formed between the metal plates 50a and 52a by the current i1. If the branch current i2 continues to flow, the total energization amount of the current i1 is reduced as compared with the case where the branch current i2 is stopped, so that the heating region 70 and thus the nugget 78 tend to be slightly reduced.

  Therefore, when the nugget 78 is further grown, it is preferable to continue energization from the upper chip 38 to the lower chip 32 by separating only the auxiliary electrodes 68a and 68b from the metal plate 54a as shown in FIG. This is because the current value of the current i1 increases as the auxiliary electrodes 68a and 68b move away from the metal plate 54a, and the total energization amount of the current i1 until the energization ends is increased.

  In this case, since the branch current i2 disappears, only the current i1 from the upper chip 38 toward the lower chip 32 flows through the metal plate 54a. As a result, the heating region 74 (see FIG. 10) disappears.

  On the other hand, in the metal plates 50a and 52a, a state similar to that during normal spot welding is formed. That is, in the metal plates 50a and 52a having a large thickness, the amount of heat generated by Joule heat increases, and as a result, the heating region 70 increases and the temperature further increases. The contact surfaces of the metal plates 50a and 52a are heated by the heating region 70 having the increased temperature, whereby the temperature in the vicinity of the contact surfaces is sufficiently increased and melted, and the growth of the melted portion (nugget 78) is promoted. The

  Thereafter, energization may be continued until the melted portion (nugget 78) is sufficiently grown, for example, until it is integrated with the melted portion that becomes the nugget 76 as shown in FIG. The degree of growth of the nugget 78 relative to the energization duration may be confirmed in advance by a spot welding test using a test piece or the like.

  Here, the contact surfaces of the metal plates 50a and 52a are preheated by the heating region 70 formed when the current i1 passes when the nugget 76 is grown between the metal plates 52a and 54a. . For this reason, the familiarity between the metal plates 50a and 52a is improved before the melted portion that becomes the nugget 78 grows. Therefore, it is difficult for spatter to occur.

  As described above, according to the second embodiment, when the nugget 76 between the metal plates 52a and 54a is grown, spatter is generated both when the nugget 78 between the metal plates 50a and 52a is grown. Can be avoided.

  After a predetermined time has passed and the melted portion that will become the nugget 78 has sufficiently grown, the energization is stopped and the upper chip 38 is separated from the metal plate 54a as shown in FIG. Alternatively, the upper chip 38 and the lower chip 32 may be electrically insulated by separating the upper chip 38 from the metal plate 54a.

  All the operations described above from the start to the end of spot welding are performed under the control action of the gun controller 58.

  As the energization is stopped in this manner, the heat generation of the metal plates 50a and 52a is also terminated. As the time elapses, the melted portion is cooled and solidified, whereby the metal plates 50 a and 52 a are joined to each other via the nugget 78.

  As described above, the metal plates 50a and 52a and the metal plates 52a and 54a constituting the laminate 48a are joined together, and a joined product as a product is obtained.

  In this bonded product, the bonding strength between the metal plates 52a and 54a is excellent as well as the bonding strength between the metal plates 50a and 52a. This is because the nugget 76 between the metal plates 52a and 54a is sufficiently grown with the branch current i2 flowing through the metal plate 54a as described above.

  Moreover, as understood from the above, when the spot welding apparatus according to the second embodiment is configured, auxiliary electrodes 68a and 68b and a displacement mechanism for displacing the auxiliary electrodes 68a and 68b may be provided. . Therefore, the configuration of the spot welding apparatus is not complicated with the provision of the auxiliary electrodes 68a and 68b.

  Also in the second embodiment, the object to be welded is not particularly limited to the laminate 48a, and it is possible to weld various laminates having different numbers, materials, and thicknesses of metal plates. Hereinafter, this point will be described with a specific example.

  As described above, the laminate 48b shown in FIG. 13 is formed such that the metal plate 52b having the minimum thickness is sandwiched between the metal plates 50b and 54b. For example, the metal plate 50b is a high resistance work made of high-tensile steel, and the metal plates 52b and 54b are low resistance work made of mild steel.

  When spot welding is performed on the laminate 48b using only the upper chip 38 and the lower chip 32, the contact surfaces of the metal plates 50b and 52b are preferentially melted. This is because the contact resistance of the metal plates 50b and 52b is larger than the contact resistance of the metal plates 52b and 54b because the metal plate 50b is a high resistance work. Therefore, if energization from the upper chip 38 to the lower chip 32 is continued to sufficiently grow nuggets on the contact surfaces of the metal plates 52b and 54b, there is a concern that spatter is generated from the contact surfaces of the metal plates 50b and 52b.

  On the other hand, according to the second embodiment using the auxiliary electrodes 68a and 68b, as shown in FIG. 13, the heating region 80 is provided on both the contact surfaces of the metal plates 50b and 52b and the contact surfaces of the metal plates 52b and 54b. , 82 are formed. This is because the contact surface of the metal plates 52b and 54b is sufficiently heated by the branch current i2 flowing in the metal plate 54b, as in the case of the laminate 48a.

  Thereby, the nuggets 83 and 84 shown in FIG. 14 are formed. By continuously flowing the current i1 after the branch current i2 has disappeared, for example, as shown in FIG. 15, it straddles both the contact surfaces of the metal plates 50b and 52b and the contact surfaces of the metal plates 52b and 54b. Thus, a sufficiently grown nugget 85 can be formed.

  As can be understood from the above description regarding spot welding to the laminates 48a and 48b, by using the auxiliary electrodes 68a and 68b, the heating region, and thus the nugget is brought close to the side on which the auxiliary electrodes 68a and 68b are in contact. Can be moved to.

  Of course, the metal plate 50b is not particularly limited to the combination of high-tensile steel and the metal plates 52b and 54b are mild steel.

  Next, FIG. 16 shows a case where spot welding is performed using auxiliary electrodes 68a and 68b on a laminate 48c in which a metal plate 52c made of high-tensile steel is laminated on a metal plate 50c made of high-tensile steel. When the auxiliary electrodes 68a and 68b are not used, as shown in FIGS. 23 and 24, the melted portion 6 grows greatly in a relatively short time on the contact surfaces of the metal plates 50c and 52c (high resistance workpieces 1 and 2). . For this reason, sputtering is likely to occur.

  On the other hand, according to the second embodiment using the auxiliary electrodes 68a and 68b, as shown in FIG. 16, the heating region 86 is formed on the contact surface of the metal plates 50c and 52c, and the metal plates 50c and 52c The heating region 87 is formed above the contact surface, in other words, on the side close to the auxiliary electrodes 68a and 68b in the metal plate 52c. This is because the inside of the metal plate 52c is sufficiently heated by the branch current i2 flowing through the metal plate 52c. That is, also in this case, the heating region, and thus the nugget (see FIG. 17) can be moved so as to be close to the side on which the auxiliary electrodes 68a and 68b are in contact.

  As a result, the contact surfaces of the metal plates 50c and 52c are softened to improve the sealing performance. Therefore, even if the current i1 is continuously supplied so as to form the sufficiently grown nugget 88 as shown in FIG.

  Next, a case where spot welding is performed on the laminate 48d shown in FIG. 18 will be described. The laminated body 48d is formed by laminating a low-resistance metal plate 50d made of mild steel, high-resistance metal plates 52d and 54d made of high-tensile steel, and a low-resistance metal plate 90d made of mild steel in this order from below. The Further, the thickness of the metal plates 50d and 90d is set smaller than that of the metal plates 52d and 54d.

  In this case, auxiliary electrodes 68a and 68b are provided on the upper chip 38 side, and auxiliary electrodes 68c and 68d are provided on the lower chip 32 side. These auxiliary electrodes 68c and 68d are electrically connected to the positive electrode of the power source 56, and therefore the polarity is opposite to that of the lower chip 32. A displacement mechanism (such as a ball screw mechanism or a cylinder mechanism) for displacing the auxiliary electrodes 68c and 68d may be provided on the fixed arm 30 (see FIG. 1), for example.

  First, as shown in FIG. 18, only the auxiliary electrodes 68a and 68b are brought into contact with the metal plate 90d at the same time as or before and after the laminated body 48d is sandwiched between the upper chip 38 and the lower chip 32. Thereafter, energization is started, and a current i1 from the upper chip 38 toward the lower chip 32 and a branch current i2 from the upper chip 38 toward the auxiliary electrodes 68a and 68b are passed. As a result, nuggets 92 and 94 are formed on the contact surfaces of the metal plates 52d and 54d and the contact surfaces of the metal plates 54d and 90d, respectively.

  Next, as shown in FIG. 19, the electrical connection between the auxiliary electrodes 68a and 68b and the negative electrode of the power source 56 is cut off so that the branch current i2 disappears, or at the same time, the auxiliary electrodes 68c and 68d are made of metal. It abuts on the plate 50d. Thereby, a branch current i3 from the auxiliary electrodes 68c and 68d toward the lower chip 32 flows inside the lowermost metal plate 50d.

  As the branch current i2 disappears, the growth of the nugget 94 stops. On the other hand, since the current i1 from the upper chip 38 toward the lower chip 32 continues to flow, the nugget 92 on the contact surface of the metal plates 52d and 54d grows and the branch current i3 causes the metal plates 50d and 52d to A nugget 96 is newly formed on the contact surface.

  Next, as shown in FIG. 20, the auxiliary electrodes 68c and 68d are separated from the metal plate 50d to eliminate the branch current i3, thereby stopping the growth of the nugget 96. After that, by continuously flowing the current i1, only the nugget 92 on the contact surface of the metal plates 52d and 54d can be grown and integrated with the nuggets 94 and 96, for example.

  In the second embodiment described above, the auxiliary electrodes 68a and 68b are separated from the metal plate 54a prior to the upper chip 38. However, the auxiliary electrodes 68a and 68b and the upper chip 38 are simultaneously removed from the metal plate 54a. You may make it space apart.

  Further, as shown in FIG. 21, a current from the lower chip 32 in contact with the metal plate 50a toward the upper chip 38 in contact with the metal plate 54a may be passed. Also in this case, the polarities of the auxiliary electrodes 68a and 68b in contact with the metal plate 54a are reversed from those of the upper chip 38. That is, the lower chip 32 and the auxiliary electrodes 68 a and 68 b are electrically connected to the positive electrode of the power source 56, while the upper chip 38 is electrically connected to the negative electrode of the power source 56. As a result, a current i1 from the lower chip 32 toward the upper chip 38 and a branch current i2 from the auxiliary electrodes 68a and 68b toward the upper chip 38 are generated.

  Further, as shown in FIG. 22, the branch current i2 may flow not only to the metal plate 54a in contact with the upper chip 38 but also to the metal plate 52a located immediately below the metal plate 54a.

  Then, instead of separating the auxiliary electrodes 68a and 68b from the metal plate 54a, a switch is provided between the auxiliary electrodes 68a and 68b and the power source 56, and this switch is turned off to turn off the upper chip. Only the branch current from 38 to the auxiliary electrodes 68a and 68b or the branch current flowing in the opposite direction may be stopped. In this case, in order to form the heating region 74, it goes without saying that the switch is connected (ON).

  In this case, it is not particularly necessary to provide a displacement mechanism for displacing the auxiliary electrodes 68a and 68b separately from the upper chip 38. For this reason, there is an advantage that the device configuration and operation control are further simplified.

  In any case, the auxiliary electrode is not particularly limited to the two long rod-shaped auxiliary electrodes 68a and 68b. For example, one or three or more long rod-shaped bodies may be used. When three or more electrodes are used, a plurality of auxiliary electrodes 68a and 68b may be simultaneously brought into contact with or separated from the outermost metal plate, as in the case of the above two. Further, the auxiliary electrode may be of an annular shape surrounding the lower chip 32 or the upper chip 38.

  In addition, in the configuration of the spot welding apparatus according to the second embodiment, if the auxiliary electrodes 68a and 68b and the power source 56 are electrically insulated, the spot welding method according to the first embodiment can be implemented. That is, according to the configuration of the spot welding apparatus according to the second embodiment, the spot welding method according to the second embodiment or the first is selected by selecting whether or not to pass current to the auxiliary electrodes 68a and 68b. Either of the spot welding methods according to the embodiment can be selected.

  Furthermore, in the first embodiment and the second embodiment described above, the C-type welding gun has been exemplified and described, but the welding gun may be a so-called X-type. In this case, the lower chip 32 and the upper chip 38 are provided on each of a pair of chuck claws that can be freely opened and closed, and the pair of chuck claws are opened or closed so that the lower chip 32 and the upper chip 38 are connected. What is necessary is just to make it mutually separate or approach.

  Of course, the laminate may be composed of five or more metal plates.

3, 8, 48a to 48d ... Laminate 6, 9 ... Melting zone 10 ... Spot welding device 14 ... Welding gun 24 ... Gun body 30 ... Fixed arm 32 ... Lower tip 34 ... Connecting rod 38 ... Upper tip 42a, 42b ... Cylinder Mechanisms 46a, 46b ... Pressure rods 50a-50d, 52a-52d, 54a-54d, 90d ... Metal plate 56 ... Power source 58 ... Gun controllers 60, 62, 70, 72, 74, 80, 82, 86, 87 ... Heating Region 64, 66, 76, 78, 83-85, 88, 92, 94, 96 ... Nuggets 68a-68d ... Auxiliary electrodes

Claims (7)

A spot welding method for performing spot welding on a laminate formed by laminating a plurality of workpieces,
The laminated body is sandwiched between the first welding tip and the second welding tip, and a pressure member is brought into contact with the outermost work that is located on the outermost side of the laminated body and is in contact with the first welding tip. , The step of pressurizing the laminate from the outermost work side by the pressurizing member;
Maintaining the pressure applied by the pressure member and energizing between the first welding tip and the second welding tip;
A spot welding method characterized by comprising:   2. The spot welding method according to claim 1, wherein the pressurizing member is configured by an auxiliary electrode having a polarity opposite to that of the first welding tip, and energization is performed between the first welding tip and the second welding tip. At this time, either a branch current from the first welding tip toward the auxiliary electrode or a branch current from the auxiliary electrode toward the first welding tip is generated.   The spot welding method according to claim 2, wherein another auxiliary electrode having a polarity opposite to that of the second welding tip is provided on the second welding tip side, and a branch current from the first welding tip toward the auxiliary electrode, Or, after erasing any of the branch current from the auxiliary electrode toward the first welding tip, the branch current from the other auxiliary electrode toward the second welding tip, or from the second welding tip to the separate current A spot welding method characterized by flowing one of branch currents directed to the auxiliary electrode. A spot welding apparatus for performing spot welding on a laminate formed by laminating a plurality of workpieces,
A first welding tip and a second welding tip for sandwiching the laminate,
A pressing member for contacting a portion of the outermost work positioned on the outermost side of the layered body different from a portion contacted by the first welding tip, and pressurizing the laminated body from the outermost work side; ,
A pressurizing mechanism for generating a pressurizing force on the pressurizing member;
A spot welding apparatus comprising:   5. The spot welding apparatus according to claim 4, further comprising a robot that supports a welding gun provided with the first welding tip and the second welding tip, and the pressurizing mechanism is provided in the welding gun. A feature spot welding device.   6. The spot welding apparatus according to claim 4, wherein the pressing member is an auxiliary electrode having a polarity opposite to that of the first welding tip, and is energized between the first welding tip and the second welding tip. When performing, a spot welding apparatus characterized by generating either a branch current from the first welding tip toward the auxiliary electrode or a branch current from the auxiliary electrode toward the first welding tip.   7. The spot welding apparatus according to claim 6, further comprising another auxiliary electrode that is provided on the second welding tip side and has a polarity opposite to that of the second welding tip, from the first welding tip to the auxiliary electrode. Either the branch current directed to the first welding tip from the auxiliary electrode, or the branch current directed to the second welding tip from the other auxiliary electrode, or the second A spot welding apparatus that generates any one of branch currents directed from the welding tip to the other auxiliary electrode.

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