JP2006035295A - Friction point-joining method, and its device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a friction point-joining method and its device for performing the friction point-joining of at least three stacked metal plate members using a rotary tool in which the friction point-joining of consistent quality is performed by inputting the friction heat to the metal plate members step by step. <P>SOLUTION: A projecting part 11 on the tip, a first shoulder part 12 having the diameter larger than that of the projecting part 11, and a second shoulder part 13 having the diameter larger than that of the first shoulder part 12 and relatively movable in the direction of the axis of rotation are provided on a rotary tool 10. Metal plate members W1, W2, W3 are received by a receiving tool 20 arranged opposite to the rotary tool 10, and pressed by the rotating rotary tool 10 to push the projecting part 11 and the first shoulder part 12. When the projecting part 11 reaches an area of the third metal plate member W3, the second shoulder part 13 is relatively moved, the first metal plate member W1 is pressed, joining parts of the metal plate members W1, W2, W3 are softened by the frictional heat, and subjected to plastic flow to perform the joining. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a friction point joining method and apparatus for friction spot joining in which at least three metal plate members are stacked and friction point joined with a rotary tool.

Conventionally, a rotary tool having a protruding portion at the tip, a first shoulder portion having a diameter larger than the protruding portion, and a second shoulder portion having a diameter larger than the first shoulder portion is used to face the rotating tool. Then, placing the receiving tool, receiving the metal plate member with the receiving tool, pressing the rotating tool in a rotated state, pressing the protruding portion and the first shoulder portion, and further pressing the rotating tool, A friction point joining method is known in which the metal plate member is pressed by the second shoulder portion, the joining portion of the metal plate member is softened by frictional heat, and is plastically flowed to join (for example, see Patent Document 1). ).
JP 2002-292479 A

  However, in the conventional friction point joining method, the distance between the tip end surface of the protruding portion and the tip end surface of the second shoulder portion is fixed. If there is a plate assembly, the second shoulder portion comes into contact with the first metal plate member before the protrusion reaches the region of the third metal plate member from the rotary tool, In some cases, the necessary frictional heat cannot be input to the third metal plate member, and the metal plate members are not sufficiently bonded to each other.

  In such a case, if the rotary tool is further pushed in and the protrusion reaches the third metal plate member to apply the necessary frictional heat, the second shoulder portion further becomes the first metal plate member. The frictional heat is input more than necessary and heat distortion occurs. As a result, the metal plate members around the rotating tool are warped and a gap is generated between the metal plate members, so that appropriate friction point joining cannot be performed.

  On the other hand, as another means for performing friction point joining by applying appropriate heat to each metal plate member, there is a method of exchanging the rotary tool in accordance with the configuration of the plate thickness. However, exchanging the rotating tool in accordance with the configuration of the metal plate member has a problem that the number of steps increases correspondingly and the time required for friction point joining increases.

  The present invention has been made in view of such a point, and the object of the present invention is to apply frictional heat to the metal plate member stepwise by adding a device to the contact timing of the second shoulder portion of the rotary tool. It is to be able to perform friction point welding with stable quality by inputting.

  In order to achieve the above object, in the present invention, the second shoulder portion of the rotary tool can be moved relative to the first shoulder portion in the direction of the rotation axis.

  Specifically, the first invention is directed to a method of stacking at least three metal plate members and performing friction point joining with a rotary tool.

  And the protrusion part of a front-end | tip, the 1st shoulder part with a larger diameter than this protrusion part, and the 2nd shoulder part arrange | positioned so that a diameter is larger than this 1st shoulder part, and it can move relatively to a rotation axis direction A rotating tool is prepared, and a receiving tool arranged to face the rotating tool is prepared. The metal plate member is received by the receiving tool and is pressed by the rotating rotating tool so as to receive the protruding portion and the second rotating tool. 1 shoulder part is pushed in, the metal plate member is pressed by moving the second shoulder part relative to the metal plate member in the state where the protruding part reaches the region farthest from the rotary tool, and the joint part of the metal plate member Are softened by frictional heat and plastically flowed to join.

  According to the above configuration, even if there is a set of plates having different thicknesses in the same friction spot joining process, the second shoulder portion can be moved relative to each other without changing the rotating tool according to the configuration of the plate thickness. In addition, it is possible to input an appropriate frictional heat according to the structure of the plate thickness. That is, in the state in which the protruding portion reaches the region of the metal plate member farthest from the rotating tool, the second shoulder portion is relatively moved to press the metal plate member closest to the rotating tool. Appropriate frictional heat corresponding to the plate thickness is input without inputting frictional heat to the plate member more than necessary. Accordingly, a new process for replacing the rotary tool is not required, and the time required for the friction point joining does not increase.

  The second invention is directed to a friction point joining apparatus in which at least three metal plate members are stacked, and a joining portion of the metal plate members is softened by frictional heat with a rotary tool and plastically joined.

  And the protrusion part of a front-end | tip, the 1st shoulder part whose diameter is larger than this protrusion part, the diameter is larger than this 1st shoulder part, and it arrange | positions with respect to this 1st shoulder part so that a relative movement is possible in a rotation axis direction A rotating tool having a second shoulder portion formed thereon, a receiving tool disposed opposite to the rotating tool, a rotating means for rotating the rotating tool, a protruding portion of the rotating tool, and a first shoulder portion. In a state where the pressing means that presses the metal plate member, the moving means that presses the metal plate member by relatively moving the second shoulder portion, and the protrusion reaches the region of the metal plate member farthest from the rotating tool, Control means for moving the second shoulder portion relative to the moving means.

  According to the above configuration, the control means presses the metal plate member closest to the rotary tool by relatively moving the second shoulder portion in a state where the protrusion reaches the region of the metal plate member farthest from the rotary tool. Therefore, even if there are plate sets with different plate thicknesses within the same friction spot joining process, if the second shoulder portion is moved relative to the plate without changing the rotating tool to match the plate thickness configuration, The frictional heat can be input according to the configuration. Therefore, the frictional heat is not input to the nearest metal plate member more than necessary, and the appropriate frictional heat according to the plate thickness is input, so there is no need to newly replace the rotating tool and the friction point. The time required for joining does not increase.

  As described above, according to the first and second inventions described above, the metal plate member is moved by relatively moving the second shoulder portion in a state where the protruding portion reaches the region of the metal plate member farthest from the rotary tool. Pressing. For this reason, friction heat can be input to each metal plate member step by step without replacing the rotating tool according to the configuration of the plate thickness, enabling efficient friction point joining and stable joining. Quality is obtained.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, the following embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or a use.

-Configuration of friction spot welding device-
FIG. 1 shows a schematic configuration of a friction point welding apparatus 1 according to an embodiment of the present invention. The friction point joining apparatus 1 is configured to join a plurality of metal plate members made of light metal such as an aluminum alloy used for an automobile body or the like in a state of being stacked in a thickness direction.

  The joining apparatus includes a joining gun 2 that joins workpieces W. The work W includes three first to third metal plate members W1, W2, and W3 (shown in FIG. 2). The joining gun 2 is attached to the arm 3a of the robot 3 and is positioned by the robot 3 at the joining position of the workpiece W fixed to a jig (not shown) so as to join the workpiece W.

  As the robot 3, for example, a general-purpose 6-axis vertical articulated robot can be used. The robot 3 is connected to a control panel 5 as control means by a robot harness 4. The joining gun 2 is also connected to the control panel 5 by a joining gun harness 7 via a relay box 6 provided in the robot 3.

  As shown in FIG. 2, the joining gun 2 includes a rotary tool 10 and a receiving tool 20.

  The rotary tool 10 is disposed on the upper side of the joining axis X that is orthogonal to the overlapping surfaces S1, S2 of the stacked metal plate members W1, W2, W3. As shown in FIG. 3, the rotary tool 10 includes a protruding portion 11 at the tip, a first shoulder portion 12 having a diameter larger than that of the protruding portion 11, and a diameter larger than that of the first shoulder portion 12 in the direction of the rotation axis. And a second shoulder portion 13 arranged to be relatively movable. Further, the second shoulder portion 13 is covered with a mounting portion 9 having an outer shape larger than that of the second shoulder portion 13. The attachment portion 9 is provided with a flange portion 9b having a hollow portion 9a in the center.

  The receiver 20 is attached to the tip of a substantially L-shaped gun arm 8. Thus, the rotary tool 10 and the receiving tool 20 are disposed so as to face each other.

  The receiver 20 has a columnar shape, and the distal end surface thereof has an outer diameter that is equal to or larger than the distal end surface of the second shoulder portion 13 of the rotary tool 10.

  The protruding portion 11, the first shoulder portion 12, and the second shoulder portion 13 are provided so as to extend coaxially on the joining axis X. The outer diameter of the protrusion 11 is 2 to 5 mm, for example.

  Next, the mechanism inside the joining gun 2 will be briefly described. The rotary tool 10 is configured to rotate around the joining axis X (for example, counterclockwise in FIG. 2) by a rotary shaft motor 14 as a rotating means. That is, the rotary tool 10 is fixed to the mounting flange 15 a of the cylindrical turning shaft 15. The upper end of the pivot shaft 15 is fixed to the ball spline 40. A first pulley 16 is attached to the upper end of a cylindrical turning drive source shaft 43 that is spline-coupled to the ball spline 40 and rotatably supported by a gun body 41 via a bearing 42. On the other hand, a second pulley 17 is attached to the rotary shaft of the rotary shaft motor 14, and the first pulley 16 is driven via a toothed belt 18 driven by the second pulley 17, and the turning drive source shaft 43, the ball The rotary tool 10 rotates through the spline 40 and the turning shaft 15. Furthermore, the rotary tool 10 is configured to move up and down on the joining axis X by a pressing shaft motor 44 as pressing means. That is, a cylindrical elevating cylinder 47 is provided on an elevating member 46 that is screwed up and down with a ball screw 45 that is rotatably arranged on the gun body 41, and the lower end side of the elevating cylinder 47 can be raised and lowered on the gun body 41. It is supported by. The ball spline 40 and the turning shaft 15 are rotatably supported inside the elevating cylinder 47 via a bearing 48. On the other hand, a third pulley 49 is attached to the rotating shaft of the pressing shaft motor 44, and the fourth pulley 51 attached to the ball screw 45 is driven via a toothed belt 50 driven by the third pulley 49. As a result of this rotation, the elevating member 46 and the elevating cylinder 47 are moved up and down, the ball spline 40 and the turning shaft 15 are moved up and down via the bearing 48, and the rotary tool 10 is moved up and down on the joining axis X. As the rotary shaft motor 14, an induction motor or a servo motor can be used, and as the pressing shaft motor 44, a servo motor can be used.

  Next, the structure of the moving means 21 for relatively moving the second shoulder portion 13 of the rotating tool 10 will be described. As shown in enlarged views in FIGS. 3 and 4, the flange portion 9 b of the attachment portion 9 of the rotary tool 10 is non-rotatably attached to the attachment flange 15 a of the pivot shaft 15 by a bolt (not shown). Further, the base end portion of the first shoulder portion 12 is fixed to the inner surface of the attachment portion 9. The second shoulder portion 13 is inserted between the attachment portion 9 and the first shoulder portion 12.

  The first shoulder portion 12 is formed in a hollow bottomed cylindrical shape, and the protruding portion 11 protrudes from the distal end surface (bottom surface) of the first shoulder portion 12. A pair of long holes 12 a parallel to the joint axis X are formed on the side surfaces of the first shoulder portion 12.

  The second shoulder portion 13 is formed in a cylindrical shape, and a rectangular plate member 22 orthogonal to the joining axis X is fixed to the inner surface thereof. A columnar joint 23 is coupled to the plate member 22. The joint portion 23 is coupled by a columnar joint portion 24 disposed in the hollow portion 9 a of the mounting portion 9 and a bar member 25.

  The plate member 22 of the second shoulder portion 13 is inserted into the long hole 12 a of the first shoulder portion 12. That is, the second shoulder portion 13 is disposed so as to be relatively movable in the direction in which the joining axis X extends with respect to the first shoulder portion 12 and the attachment portion 9.

  The joint portion 24 of the second shoulder portion 13 is joined to the distal end portion of the long propulsion shaft 26 inserted into the mounting flange 15 a and the through hole of the turning drive source shaft 43. The propulsion shaft 26 is a propulsion shaft of the linear motor 27, and by driving the linear motor 27, the second shoulder portion 13 coupled to the propulsion shaft 26 is connected to the first shoulder portion 12 and the attachment portion 9. Relative movement in the direction in which the joining axis X extends. The linear motor 27 is provided in the upper casing 28 of the joining gun 2 above the first pulley 16.

  The control panel 5 is configured to synchronously control a total of nine axes of the six axes of the robot 3 and the rotary shaft motor 14, the pressing shaft motor 44, and the linear motor 27 of the moving means 21 provided on the joining gun 2. Yes. The control panel 5 controls the robot 3 to support the metal plate members W1, W2, and W3 stacked by the support 20, and controls the joining gun 2 so that the protruding portion 11 is the third metal plate member W3. In the state which reached | attained the area | region, the said 2nd shoulder part 13 is relatively moved by the said moving means 21, and it pushes into the said metal plate member W1. Then, the metal plate members W1, W2, and W3 are softened by the frictional heat of the rotary tool 10, and control is performed so that the joining portions are joined by plastic flow.

-Work W Joining Method 1 (Monitoring Method)-
Next, the joining method 1 of the workpiece | work W by the friction point joining apparatus 1 concerning embodiment of this invention is demonstrated.

  (1) First, the initial state of the friction spot welding apparatus 1 will be described.

  The workpiece W is fixed by a jig (not shown). Of the three stacked metal plate members W1, W2, and W3, which are bonding materials, the front end surface of the second shoulder portion 13 has a thickness t1 of the first metal plate member W1 and a thickness t2 of the second metal plate member W2. Is positioned at a base end side of the rotary tool 10 with respect to the front end surface of the first shoulder portion 12 with a length of about 1.5 times or more of the sum L1 (L1 = t1 + t2). The robot 3 is at the origin position, and the joining gun 2 is at the open end position (that is, the state in which the rotary tool 10 is farthest from the receptacle 20 as shown in FIG. 1).

  (2) Next, the teaching work of the robot 3 will be described.

  First, the welding parameters such as the applied pressure, the rotation speed, and the time are input.

  Next, the origin position for monitoring the position of the rotary tool 10 by the pressing shaft motor 44 is taught. That is, as shown in FIG. 6, a state in which the metal plate members W1, W2, and W3 are sandwiched between the rotary tool 10 and the receiving tool 20 is taught. The encoder value of the pressing shaft motor 44 corresponding to the position of the rotary tool 10 at that time is set to zero.

  Next, the timing at which the second shoulder portion 13 is ejected is defined as a position where the rotary tool 10 has advanced a predetermined distance from the origin in the pressing direction, and the distance L1 is input as a parameter in teaching.

  Next, the final arrival position of the second shoulder portion 13 is defined as that the distal end surface thereof is closer to the proximal end side of the rotary tool 10 as the position of 80 to 100% of the distance L1 with the distal end of the protruding portion 11 as a base point. The distance L2 is input as a parameter (0.8L1 ≦ L2 ≦ 1.0L1).

  (3) Next, operations of the robot 3 and the joining gun 2 will be described.

  First, the robot 3 starts operating from the origin. Further, the position of the rotary tool 10 is monitored on the control panel 5.

  Next, the joining gun 2 is positioned by the robot 3 at the teaching point immediately before the pressurizing point. Specifically, as shown in FIG. 5, the workpiece W is positioned between the rotary tool 10 of the bonding gun 2 and the receiving tool 20, and the bonding portion of the workpiece W is positioned on the bonding axis X.

  Next, as shown in FIG. 6, while receiving the stacked metal plate members W1, W2, and W3 by the receiving tool 20, the rotary tool 10 is rotated around its joining axis X by the rotary shaft motor 14, and the pressing shaft The protrusion 44 of the rotary tool 10 is pushed into the first metal plate member W1 by the motor 44. Thus, the metal plate members W1, W2, and W3 are held between the rotary tool 10 and the receiving tool 20.

  Next, pressurization of the rotary tool 10 is started. Thereby, the protrusion part 11 sinks in the 1st metal plate member W1.

  Next, as shown in FIG. 7, the rotary tool 10 is further pushed in so that the protruding portion 11 sinks to the area of the second metal plate member W2, and the tip of the first shoulder portion 12 also sinks into the first metal plate member W1. Include.

  Next, as shown in FIG. 8, when the rotary tool 10 has passed a predetermined position taught from the origin (advanced to the length of L1), a command is issued to the linear motor 27 and the second shoulder portion 13 is lowered. Let

  Next, as shown in FIG. 9, the second shoulder portion 13 is moved toward the inside of the workpiece W by the linear motor 27 to the final arrival position (position L2 from the tip of the protruding portion 11). The joint part is softened by frictional heat.

  As a result, plastic flow is generated in the workpiece W, and the first recess is formed by the rotating tool 10 with the protruding portion 11 penetrating the interface S1 between the first metal plate member W1 and the second metal plate member W2. 31 is formed. On the outer side of the first recess 31, an annular first swelled portion 33 is formed in which the second metal plate member W2 swells toward the first plate member W1 over the entire circumference. Moreover, the 2nd recessed part 32 is formed by the protrusion part 11, leaving the continuous interface S2 between the 2nd metal plate member W2 and the 3rd metal plate member W3. On the outer side of the second recess 32, an annular second swelled portion 34 is formed in which the third metal plate member W3 rises toward the second metal plate member W2 over the entire circumference.

  Next, when the joining time reaches the time taught in advance, the operation is switched to the opening operation. Specifically, the rotary tool 10 is moved backward by the pressing shaft motor 44 and pulled out from the workpiece W while the rotary tool 10 is rotated. As a result, the workpiece W is rapidly cooled, cured, and bonded.

  Next, the rotation of the rotary tool 10 is stopped in a state of being separated from the joining position by a predetermined distance set in advance, and the second shoulder portion 13 of the rotary tool 10 is returned to the original position.

  Next, the joining gun 2 is positioned at the teaching release point.

  Then, the joining gun 2 moves to the next teaching point, and the joining of the workpiece W is repeated.

-Work W joining method 2 (Method by time setting)-
Next, a joining method different from the joining method 1 for the workpiece W will be described. The bonding method 1 is a bonding method based on monitoring, whereas the bonding method 2 is a bonding method based on time setting.

  (1) First, the initial state is the same as that of the bonding method 1 described above.

  (2) Next, the teaching work of the robot 3 is almost the same as the joining method 1 described above, but the time at which the pressurizing point taught by the rotary tool 10 is reached during automatic operation is used as a time reference. The second shoulder portion 13 is brought out when a predetermined time T1 has elapsed. That is, the elapsed time T1 from when the metal plate members W1, W2, and W3 are sandwiched between the rotary tool 10 and the receiving tool 20 is input as a parameter.

  (3) Next, operations of the robot 3 and the joining gun 2 will be described.

  First, the robot 3 starts operating from the origin.

  Next, the joining gun 2 is positioned by the robot 3 at the teaching point immediately before the pressurizing point in a state where the joining axis X coincides with the joining direction of the workpiece W.

  Next, similarly to the joining method 1, the receiving tool 20 and the rotary tool 10 are brought into contact with the metal plate members W1, W2, and W3 at the same timing, and the metal plate members W1, W2, and W3 are sandwiched.

  Next, pressurization of the rotary tool 10 is started. Thereby, the protrusion 11 sinks into the first metal plate member W1.

  Next, the rotary tool 10 is further pushed in, and the protrusion 11 sinks to the area of the second metal plate member W2.

  Next, when a predetermined time T1 when the rotary tool 10 starts teaching (contact with the first metal plate member W1) has elapsed, a command is issued to the linear motor 27 and the second shoulder portion 13 is lowered. Let

  Next, the second shoulder portion 13 is moved by the linear motor 27 toward the inside of the workpiece W to the final position (the position L2 from the tip of the protruding portion 11), and in this state, the joining portion is moved by the frictional heat of the rotary tool 10. Soften. The moving distance may be after a predetermined time has elapsed from the start of the lowering of the second shoulder portion 13, or the advance of the predetermined distance L <b> 2 may be detected from the encoder value of the linear motor 27.

  Since the subsequent operation is the same as that of the bonding method 1, the description thereof is omitted.

-Effect of the embodiment-
Therefore, according to the friction point joining method and apparatus according to the embodiment of the present invention, the metal plate member is moved by relatively moving the second shoulder portion 13 in a state where the protruding portion 11 reaches the region of the third metal plate member W3. W1, W2, and W3 are pressed. For this reason, it is possible to input frictional heat to each metal plate member W1, W2, W3 step by step without replacing the rotating tool 10 in accordance with the configuration of the plate thickness. It can be performed and a stable bonding quality can be obtained.

(Other embodiments)
The present invention may be configured as follows with respect to the above embodiment.

  That is, in the said embodiment, although the workpiece | work W shall consist of the metal plate member W1, W2, W3 which accumulated 3 sheets, it is good also as what consists of 4 or more metal plate members. In this case, the second shoulder portion 13 may be further divided into two stages, and each may be arranged so as to be relatively movable with respect to the first shoulder portion 12 in the direction of the rotation axis.

  As described above, the present invention is useful for a friction point joining method and apparatus for joining a plurality of metal plate members used in an automobile body or the like in a pointed state in a stacked state.

It is a schematic explanatory drawing of the friction point joining apparatus concerning the embodiment of the present invention. It is a side view of a joining gun. It is side surface sectional drawing which expands and shows a rotary tool. It is side surface sectional drawing which decomposes | disassembles a rotary tool and shows from two directions. It is an enlarged side view of the joining part vicinity of the workpiece | work showing the process before joining. FIG. 6 is a view corresponding to FIG. 5 illustrating a process at the start of bonding. FIG. 6 is a view corresponding to FIG. 5 illustrating a step of lowering the first shoulder portion. FIG. 6 is a view corresponding to FIG. 5 illustrating a process at the start of lowering the second shoulder portion. FIG. 6 is a view corresponding to FIG. 5 illustrating a joining completion state.

Explanation of symbols

1 Friction spot welding device 5 Control panel (control means)
DESCRIPTION OF SYMBOLS 10 Rotating tool 11 Protruding part 12 1st shoulder part 13 2nd shoulder part 14 Rotating shaft motor (rotating means)
20 Receiving means 21 Moving means 44 Pressing shaft motor (pressing means)
W1, W2, W3 Metal plate member

Claims (2)

A method of stacking at least three metal plate members and performing friction point joining with a rotating tool, comprising: a protruding portion at a tip, a first shoulder portion having a diameter larger than the protruding portion, and a diameter larger than the first shoulder portion. A rotation tool having a second shoulder portion that is arranged so as to be relatively movable in the direction of the rotation axis,
Prepare a receiver placed facing the rotating tool,
The metal plate member is received by the receiver and pressed by the rotating tool to rotate, and the protrusion and the first shoulder are pushed in,
With the protrusion reaching the region of the metal plate member farthest from the rotary tool, the metal plate member is pressed by relatively moving the second shoulder portion,
A friction point joining method, comprising: joining the metal plate members by softening frictional heat and plastic flow. A friction point joining apparatus that stacks at least three metal plate members, softens the joint portion of the metal plate member with frictional heat with a rotating tool, and plastically joins the joints.
A protrusion at the tip, a first shoulder with a diameter larger than the protrusion, and a diameter larger than the first shoulder and arranged to be relatively movable in the rotational axis direction with respect to the first shoulder A rotating tool having a second shoulder portion;
A receiver disposed opposite the rotating tool;
A rotating means for rotating the rotating tool;
A pressing means for pressing the protruding portion and the first shoulder portion of the rotating tool against the metal plate member;
Moving means for relatively moving the second shoulder portion to press the metal plate member;
A friction point joining apparatus, comprising: a control means for relatively moving the second shoulder portion by the moving means in a state where the protruding portion reaches the region of the metal plate member farthest from the rotary tool.

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