JP5210770B2 - Work mounting system and work mounting method - Google Patents

Description

  The present invention relates to a workpiece mounting system and a workpiece mounting method. More specifically, the present invention relates to a work attachment system and a work attachment method for attaching a sunroof to the body of an automobile.

Conventionally, a sunroof for taking in external light is provided in the body of an automobile. This sunroof is formed by attaching a sunroof unit to the body.
That is, a sunroof unit mounting robot is arranged on the body production line (see Patent Document 1). The sunroof unit mounting robot includes a robot arm and a hand that is provided at the tip of the robot arm and supports the sunroof unit.

  The hand has a rectangular frame shape, and includes two tapered taper pins, three cylinder units, two positioning pins, and eight nut runners. Bolts are sandwiched between the nut runners. In this hand, the positions of the positioning pins and nut runners are determined in advance according to the shape of the sunroof unit.

The operation of the above mounting robot is as follows.
First, the sunroof unit is supported by the hand. Specifically, the sunroof unit is positioned with respect to the hand by inserting a positioning pin into the sunroof unit, and the bolts clamped by the nut runner of the hand are inserted into the bolt holes of the sunroof unit.
Thereafter, the robot arm is controlled to insert the sunroof unit into the body through the opening for the front window of the body.

Next, the taper taper pin of the hand is inserted into a positioning hole formed at the attachment position of the body to position the hand with respect to the body.
Next, the cylinder unit is driven to bring the sunroof unit closer to the attachment position of the body, and the nut runner is driven to screw the bolt into the nut of the body.

According to such an attachment robot, the sunroof unit can be transported and attached with one hand.
Japanese Patent No. 2672825

  By the way, in recent years, in order to operate a production line efficiently, a plurality of vehicle types are often produced on one production line. In this case, the shape of the sunroof unit may differ depending on the vehicle type.

  However, in the above-described hand structure, the positions of the positioning pins and nut runners are determined in advance according to the shape of the sunroof unit, so that the versatility is low and the hands need to be replaced for each vehicle type. Therefore, there is a problem that the cycle time is prolonged.

  It is an object of the present invention to provide a workpiece mounting system and a workpiece mounting method that are highly versatile and can reduce cycle time.

  The workpiece mounting system (for example, a workpiece mounting system 1 described later) of the present invention has a first workpiece (for example, described later) on a mounted portion (for example, an inner panel 2A described later) of a second workpiece (for example, a body 2 described later). The sunroof member 3) is a workpiece mounting system for temporarily fixing the first workpiece to the second workpiece (for example, a nut runner 23 described later), and a gripping unit for gripping the first workpiece (for example, , Positioning pins 223, workpiece support pads 224, which will be described later, and first position detection means (for example, a CCD camera 241 to be described later) for detecting the position of the first workpiece and the position of the attachment portion of the second workpiece. A robot (for example, a first mounting robot 5 described later) and a main fixing means (for example, a tightening hand described later) for fixing the first work to the second work. 70) and a control device (for example, a control device 7 described later) for controlling the first robot and the second robot, and the control The apparatus calculates the position information calculating step of calculating the position of the first workpiece and the position of the attached portion of the second workpiece as position information by the position detecting means of the first robot, and the position information calculating step. Based on the position information, the first workpiece is gripped by the gripping means of the first robot, and then the first workpiece is transported by the first robot, and the first workpiece is attached to the second workpiece. Calculated by the positioning step of positioning to the part, the temporary fixing step of temporarily fixing the first workpiece to the second workpiece by the temporary fixing means of the first robot, and the position information calculating step Based on the location information, and executes a a permanent fixing step of the fixing of the first workpiece to the second workpiece by the fixing means of the second robot.

According to this invention, the first work is attached to the attachment site of the second work in the following procedure.
First, the position detection means of the first robot calculates the position of the first workpiece and the position of the attached portion of the second workpiece as position information.
Next, based on the calculated position information, the first workpiece is gripped by the gripping means of the first robot, and then the first workpiece is transported by the first robot, and the first workpiece is transferred to the second workpiece. Position the mounting part.

  Next, the first work is temporarily fixed to the second work by the temporary fixing means of the first robot, and then the first work is fixed to the second work by the main fixing means of the second robot based on the already calculated position information. The book is fixed.

  Therefore, only the first workpiece is positioned and temporarily fixed by the first robot, and the first workpiece is permanently fixed by the second robot, and the roles of the first robot and the second robot are shared. Therefore, by making each of the first robot and the second robot optimal structures according to their roles, it is possible to cope with the case where the shape of the first workpiece varies from model to model, thus increasing versatility and reducing cycle time. it can.

  Further, the position detection means calculates the position of the first workpiece and the position of the attachment portion of the second workpiece once as position information, and based on the calculated position information, the operation of the first robot and the second robot. Correct. Therefore, it is not necessary to detect the position of the attached portion of the first work or the second work many times, so that the number of work steps can be reduced and the cycle time can be further shortened.

  The workpiece mounting method of the present invention is a workpiece mounting method for mounting a first workpiece to a mounted portion of a second workpiece, wherein the position of the first workpiece and the mounted portion of the second workpiece are adjusted by the first robot. Based on the position information calculation step for calculating the position as position information, and the position information calculated in the position information calculation step, the first robot grips the first work, and then the first robot performs the first operation. A positioning step of conveying the workpiece and positioning the first workpiece on a mounted portion of the second workpiece; a temporary fixing step of temporarily fixing the first workpiece to the second workpiece by the first robot; And a main fixing step of permanently fixing the first work to the second work by the second robot based on the position information calculated in the position information calculating step. That.

  According to the present invention, there are effects similar to those described above.

  According to the present invention, the first robot performs only positioning and temporary fixing of the first workpiece, the second robot performs permanent fixing of the first workpiece, and the roles of the first robot and the second robot are shared. . Therefore, by making each of the first robot and the second robot optimal structures according to their roles, it is possible to cope with the case where the shape of the first workpiece varies from model to model, thus increasing versatility and reducing cycle time. it can. Further, the position detection means calculates the position of the first workpiece and the position of the attachment portion of the second workpiece once as position information, and based on the calculated position information, the operation of the first robot and the second robot. Correct. Therefore, it is not necessary to detect the position of the attached portion of the first work or the second work many times, so that the number of work steps can be reduced and the cycle time can be further shortened.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is an overall perspective view of a workpiece mounting system 1 according to an embodiment of the present invention.
The workpiece attachment system 1 is for attaching a sunroof member 3 as a first workpiece to a body 2 as a second workpiece conveyed by a conveyance conveyor (not shown).

A front window opening 41 to which a front window is attached is formed on the front surface of the body 2, and a front door opening 42 to which a front door is attached is formed on both side surfaces of the body 2.
The sunroof member 3 is attached to the roof 43 of the body 2 from the inside of the body 2.

  The workpiece mounting system 1 receives the sunroof member 3 from the transfer robot 4 and the transfer robot 4 that transfers the sunroof member 3 to the vicinity of the attachment position of the body 2. A first attachment robot 5 as a pair of first robots to be attached, a second attachment robot 6 as a pair of second robots to fix the first attached sunroof member 3, the transfer robot 4, And a control device 7 that controls the first mounting robot 5 and the second mounting robot 6.

FIG. 2 is a perspective view of the sunroof member 3 and the inner panel 2A as an attached portion to which the sunroof member 3 is attached.
The sunroof member 3 includes a frame 30 having a rectangular frame shape, and a center frame 33 provided across a portion of the frame 30 facing each other.

The rectangular frame-shaped frame 30 includes a substantially U-shaped main frame 31 and a sub-frame 32 that connects tip portions of the main frame 31 that extend substantially parallel to each other.
The center frame 33 connects portions extending substantially parallel to each other in the main frame 31.
Of the frames constituting the sunroof member 3, the main frame 31 and the center frame 33 have a basic structure common to various sunroof members.

Ten bolt holes 34 are formed in the peripheral portion of the sunroof member 3. Of these bolt holes 34, those located on both front sides of the sunroof member 3 are referred to as bolt holes 34A, and those adjacent to the rear side of the bolt holes 34A are referred to as bolt holes 34B.
A positioning hole 35 is formed in the vicinity of the bolt hole 34A.

  The inner panel 2 </ b> A is a panel constituting the inside of the roof 43 of the body 2. A nut 44 is formed in the inner panel 2 </ b> A corresponding to the bolt hole 34 of the sunroof member 3. If the nut 44A corresponding to the bolt hole 34A of the sunroof member 3 is a nut 44A, a positioning hole 45 is formed in the vicinity of the nut 44A corresponding to the positioning hole 35 of the sunroof member 3. . Further, the nut 44 corresponding to the bolt hole 34B of the sunroof member 3 is referred to as a nut 44B.

  The sunroof member 3 is attached to the inner panel 2A by inserting the bolt 51 from the inside of the body 2 into the bolt hole 34 of the sunroof member 3 and screwing it into the nut 44 of the inner panel 2A. Here, the bolt 51 that is screwed into the nut 44A is referred to as a bolt 51A.

Returning to FIG. 1, the transfer robot 4 is disposed on the front side of the body 2, grips the sunroof member 3, moves toward the body 2, and moves the gripped sunroof member 3 to the inside of the body 2. Transport.
The transfer robot 4 includes a transfer hand 10 and a robot arm 11 provided on the floor surface so as to be movable along the length direction of the body 2 and changing the posture of the transfer hand 10 and the position in the three-dimensional space. Prepare.

FIG. 3 is a plan view of the transfer hand 10 of the transfer robot 4. FIG. 4 is a perspective view of the transport hand 10.
The transport hand 10 has a substantially cross shape in plan view, and has a flat base 12 extending along the central axis C of the flange surface 11A of the robot arm 11, a gripping mechanism 60 provided on the base 12, and a base 12 And a protruding portion 13 protruding along the central axis C.
The protruding portion 13 includes a support portion 131 supported by the base portion 12 and a center frame seating portion 132 provided at the tip of the support portion 131.
The lower surface of the center frame 33 is seated on the center frame seating portion 132.

  The base portion 12 includes a support portion 121 attached to the flange surface 11A of the robot arm 11, a frame portion 122 having a substantially rectangular frame shape, a connecting portion 123 that connects the frame portion 122 and the support portion 121, and the frame portion 122. A reinforcing plate 124 provided on the distal end side, and guide portions 128A and 128B provided on the frame portion 122 and extending in a direction intersecting the central axis C are provided.

Main frame seating portions 125 are provided at two corners of the frame portion 122 on the support portion 121 side.
The main frame seating portion 125 is seated on the lower surface of a portion substantially parallel to the center frame 33 of the substantially U-shaped main frame 31. The main frame seating portion 125 includes a bottom portion 126 and a pair of wall portions 127 erected on the bottom portion 126.
The pair of wall portions 127 are arranged to face each other and extend in a direction in which the central axis C intersects.

  The gripping mechanism 60 is interlocked with the movement of the pair of pressing portions 62A and 62B that can move along the guide portions 128A and 128B, the advancing and retracting mechanism 63 that moves the pressing portion 62A forward and backward along the guide portions 128A, and the pressing portion 62A. And a link mechanism 64 that moves the pressing portion 62B.

Slide guides (not shown) are provided on the upper surfaces of the guide portions 128A and 128B.
Slide rails that fit the slide guides of the guide portions 128A and 128B are provided on the lower surfaces of the pressing portions 62A and 62B, so that the pair of pressing portions 62A and 62B extends along the guide portions 128A and 128B. Can be moved.
A pressing surface 621 that is substantially perpendicular to the base portion 12 and a pressing surface 622 that is substantially parallel to the base portion 12 are provided at the distal ends of the pressing portions 62A and 62B.
The advancing / retracting mechanism 63 is attached on the frame portion 122 of the base portion 12 in a direction crossing the central axis C, a piston rod 631 having a tip attached to the pressing portion 62A, and a cylinder 632 for moving the piston rod 631 forward and backward. .

  The link mechanism 64 includes a rack 641A that is attached to the pressing portion 62A and extends in the sliding direction of the pressing portion 62A, a rack 641B that is attached to the pressing portion 62B and extends in the sliding direction of the pressing portion 62B, and a space between these racks 641A and 641B. And a pinion 642 that is rotatably provided on the central axis C and meshes with the racks 641A and 641B, and a case 643 for housing the pinion 642.

  The distance from the pressing portion 62A to the portion that meshes with the pinion 642 of the rack 641A and the distance from the pressing portion 62B to the portion that meshes with the pinion 642 of the rack 641B have the same dimensions. Thereby, even if the pressing part 62A moves along the guide part 128A, the distance from the pressing part 62A to the central axis C and the distance from the pressing part 62B to the central axis C are always constant. That is, the position of the pressing portion 62A and the position of the pressing portion 62B are always line-symmetric with respect to the central axis C.

  According to the gripping mechanism 60, when the advance / retreat mechanism 63 is driven to advance the piston rod 631, the pressing portion 62A moves outward along the guide portion 128A. Along with the movement of the pressing portion 62A, the pressing mechanism 62B also moves outward along the guide portion 128A by the link mechanism 64.

Therefore, according to the transfer hand 10 of the transfer robot 4, when the sunroof member 3 is placed on the transfer hand 10, the center frame 33 of the sunroof member 3 is seated on the center frame seating portion 132. A portion of the main frame 31 that is substantially parallel to the center frame 33 is seated on the two main frame seats 125. Specifically, a portion of the main frame 31 that is substantially parallel to the center frame 33 is fitted between the pair of wall portions 127 of the main frame seating portion 125, so that the center axis C of the sunroof member 3 is aligned. Movement along the direction is restricted.
Thereafter, by driving the gripping mechanism 60, the pressing portions 62 </ b> A and 62 </ b> B are moved outward, and the side surfaces of the main frame 31 that extend substantially parallel to each other are pressed from the inside by the pressing surface 621 to grip the gripping mechanism 60. To do. Thereby, the movement of the sunroof member 3 in the direction intersecting the central axis C within the plane of the base 12 is restricted.
In addition, the pressing surface 621 contacts the side surface of a portion of the main frame 31 that extends substantially parallel to each other, and the pressing surface 622 covers the upper surface of the portion of the main frame 31 that extends substantially parallel to each other. As a result, movement in a direction substantially perpendicular to the base 12 of the sunroof member 3 is restricted.

Returning to FIG. 1, the pair of first attachment robots 5 are disposed on both sides of the body 2 and first attach the sunroof member 3 conveyed by the conveyance robot 4 to the inner panel 2 </ b> A of the body 2.
Each of these first attachment robots 5 includes a hand 20 and a robot arm 21 provided on the floor surface to change the posture of the hand 20 and the position in the three-dimensional space.
Hereinafter, the first mounting robot 5 positioned on the left side of the body 2 will be described. The first mounting robot 5 positioned on the right side of the body 2 has the same configuration, and the appearance of the left and right first mounting robots 5 is the same. Is symmetrical with respect to the body 2.

FIG. 5 is a plan view of the hand 20 of the first mounting robot 5. FIG. 6 is a side view of the hand 20. FIG. 7 is a perspective view of the hand 20.
The hand 20 includes a substantially L-shaped support frame 22, a nut runner 23 as a temporary fixing means provided on the support frame 22, and a photographing device 24 provided on the support frame 22.

The support frame 22 includes a first frame 221 that extends in the in-plane direction from the flange surface of the robot arm 11, and a second frame 222 that extends perpendicularly to the first frame 221 from the tip of the first frame 221.
Positioning pins 223 as gripping means projecting upward are provided at the intersections of the first frame 221 and the second frame 222. Further, a work support pad 224 as a gripping means is provided on the upper surface on the tip side of the second frame 222.

The nut runner 23 is provided in the middle of the first frame 221 of the support frame 22, and includes a socket 231 into which the bolt 51 </ b> A is fitted and a drive device 232 that rotationally drives the socket 231.
According to this nut runner 23, by driving the drive device 232, the bolt 51A fitted in the socket 231 is rotated with a predetermined torque.

  The photographing device 24 is provided in the middle of the second frame 222 of the support frame 22, and a CCD camera 241 as position detecting means arranged upward, and an annular illumination device that illuminates the photographing object of the CCD camera 241. 242.

  According to the hand 20 of the first attachment robot 5, as shown in FIG. 8, when the sunroof member 3 is placed on the hand 20, the positioning pins 223 of the support frame 22 are inserted into the positioning holes 35 of the sunroof member 3. Inserted. The sunroof member 3 is supported by the positioning pins 223 and the work support pads 224 of the support frame 22. The bolt 51 </ b> A chucked by the socket 231 of the nut runner 23 is inserted into the bolt hole 34 </ b> A of the sunroof member 3.

Returning to FIG. 1, the pair of second attachment robots 6 are disposed on both sides of the body 2, and the sunroof member 3 first attached by the first attachment robot 5 is fixed to the inner panel 2 </ b> A of the body 2.
Each of these second attachment robots 6 includes a clamping hand 70 as a main fixing means, and a robot arm 71 provided on the floor and changing the posture of the clamping hand 70 and the position in the three-dimensional space. .
Hereinafter, the second mounting robot 6 positioned on the left side of the body 2 will be described. The second mounting robot 6 positioned on the right side of the body 2 has the same configuration, and the external appearances of the left and right second mounting robots 6 are as follows. Is symmetrical with respect to the body 2.

FIG. 9 is a perspective view of the clamping hand 70 of the second mounting robot 6.
The tightening hand 70 has six tightening portions 80, a switching mechanism 72 that arranges one of the tightening portions 80 at a predetermined position, a drive source 73 that rotationally drives, and the drive source 73. And an advancing / retracting mechanism 74 that is connected to the fastening portion 80 at a predetermined position.

The switching mechanism 72 is supported on the tip flange surface of the robot arm 71 via the mounting bracket 721.
The switching mechanism 72 includes a cylindrical holder 722, six fastening portions 80 disposed on the outer peripheral surface of the holder 722, and a holder driving portion 723 that rotates the holder 722.

The holder driving unit 723 is fixed to the mounting bracket 721.
The holder 722 has a cylindrical shape and is attached to the drive shaft of the holder drive unit 723. By driving the holder driving unit 723, the holder 722 rotates in the direction of the arrow A or the direction of the arrow B with the central axis as the rotation center, and moves the tightening unit 80.

FIG. 10 is a cross-sectional view of the clamping hand 70.
The tightening portion 80 is rotatably supported by the holder 722 about the rotation axis Y as a rotation center. The tightening portion 80 includes a holding portion 81, a shaft portion 82, a guide portion 83, and a bit portion 84 having a socket 85.

  The holding portion 81 has a cylindrical shape, and a ball spline 811 is provided inside the holding portion 81. The shaft portion 82 is inserted into the holding portion 81 and supported by the ball spline 811 so as to be rotatable and advanceable / retreatable.

A joint portion 821 is provided on the proximal end side of the shaft portion 82. A driving source 73 can be connected to the joint portion 821.
A spring 86 is interposed between the joint portion 821 of the shaft portion 82 and the base end surface of the holding portion 81.

  The guide portion 83 has a cylindrical shape, and the shaft portion 82 is connected to the proximal end side of the guide portion 83. Thereby, the rotational force of the shaft portion 82 is transmitted to the guide portion 83.

The proximal end side of the bit portion 84 is inserted into the distal end side of the guide portion 83. The outer peripheral surface of the base end side of the bit portion 84 and the inner peripheral surface of the guide portion 83 have a hexagonal similarity, and further, the outer peripheral surface of the base end side of the bit portion 84 and the inner peripheral surface of the guide portion 83. A slight gap is formed between the two.
As a result, the bit portion 84 is loosely fitted so as to be movable in a direction crossing the axial direction with respect to the guide portion 83 and slidable in the axial direction with respect to the guide portion 83, and can float. Further, when the guide portion 83 rotates, the bit portion 84 rotates in accordance with the rotation of the guide portion 83.
A shaft portion 82 is inserted on the base end side of the bit portion 84.

A spring 87 is built in the guide portion 83. The spring 87 is disposed along the shaft portion 82, and the distal end side of the spring 87 is housed on the proximal end side of the bit portion 84 and urges the bit portion 84 toward the distal end side.
The socket 85 holds the bolt 51. The front end surface of the socket 85 is a magnet, and the bolt 51 is held by the magnetic force of the socket 85.

According to the tightening portion 80 described above, the drive source 73 is connected to the joint portion 821 of the shaft portion 82, and the drive source 73 is rotationally driven, whereby the shaft portion 82 is rotated, and this rotational force is guided by the guide. It is transmitted to the bit part 84 through the part 83, and the socket 85 rotates.
Further, when the shaft portion 82 is pressed by the drive source 73, the shaft portion 82, the guide portion 83, and the bit portion 84 move forward while resisting the urging force of the spring 86. When released, the spring 86 is restored to the original position by the restoring force.

  Further, even if an axial pressing force acts on the socket 85, the bit portion 84 retreats against the urging force of the spring 87, so that the pressing force is relieved. Thereafter, when the pressing force is released, the bit portion 84 returns to the original position by the restoring force of the spring 87.

  The drive source 73 is disposed behind the holder 722 and includes a rotation drive unit 731. The distal end of the rotation driving unit 731 can be fitted into the joint unit 821 of the tightening unit 80. The rotation axis X of the rotation drive unit 731 is substantially parallel to the rotation axis of the holder 722.

The advance / retreat mechanism 74 is provided on the mounting bracket 721 and is controlled by the control device 7 to advance or retract the drive source 73 along the rotation axis X.
The advance / retreat mechanism 74 includes a pair of cylinder mechanisms 75 and a pair of slide guides 76.

  The pair of cylinder mechanisms 75 includes a piston rod 751 attached to the drive source 73 and a cylinder 752 for moving the piston rod 751 forward and backward. By driving the pair of cylinder mechanisms 75, the drive source 73 advances and retreats along the rotation axis X of the rotation drive unit 731.

  The pair of slide guides 76 includes a slide beam 761 attached to the drive source 73 and a slide portion 762 provided on the attachment bracket 721 and through which the slide beam 761 is inserted. The pair of slide guides 76 guide the forward and backward movement of the drive source 73 by the slide beam 761 sliding in the slide portion 762.

Next, the operation of the above-described clamping hand 70 will be described.
As an initial setting, as shown in FIG. 9, the rotation axis Y of the tightening unit 80 is located on the rotation axis X of the rotation drive unit 731 of the drive source 73.
From this state, the robot arm 71 is controlled by the control device, and the clamping hand 70 is moved to the mounting position. Specifically, the robot arm 71 is controlled so that the mounting position of the bolt 51 and the rotation axis X of the drive source 73 are coaxial.
Next, the advance / retreat mechanism 74 is driven, the drive source 73 is advanced, and the rotation drive unit 731 of the drive source 73 is connected to the shaft portion 82 of the tightening unit 80.

Subsequently, as shown in FIG. 11, the driving source 73 is further advanced by resisting the urging force of the spring 86, and the bolt 51 held by the tightening portion 80 is protruded from the front surface of the tightening hand 70. The bolt 51 is pushed out to the mounting position.
Next, the rotation drive unit 731 of the drive source 73 is driven. Then, the rotational force of the rotation driving unit 731 is transmitted to the tightening unit 80 and the socket 85 rotates. As a result, the bolt 51 is tightened at the mounting position.

Next, the advance / retreat mechanism 74 is driven, and the rotation drive unit 731 of the drive source 73 is moved backward. Then, due to the restoring force of the spring 86, the socket 85 is retracted, and the tightening portion 80 returns to the original position. Subsequently, the drive source 73 is further retracted, and the rotation drive unit 731 of the drive source 73 is separated from the shaft portion 82 of the tightening unit 80.
Next, the holder driving unit 723 is driven to rotate the holder 722 in the direction of arrow A or B, so that the rotation axis Y of the next tightening unit 80 becomes the rotation axis of the rotation driving unit 731 of the drive source 73. It arrange | positions in the position which becomes coaxial with X.

  Thereafter, the robot arm 71 is controlled by the control device, and the clamping hand 70 is moved to the next mounting position, then moved to the mounting position, and the same operation as described above is repeated.

The operation of the workpiece mounting system 1 will be described with reference to the flowchart of FIG.
In ST1, the conveyance of the body 2 is stopped.
In ST 2, the first mounting robot 5 is introduced into the body 2 through the front door openings 42 on both sides of the body 2, and the CCD camera 241 of the first mounting robot 5 is brought close to the inner panel 2 A of the roof 43. Next, the CCD camera 241 photographs the nut 44B of the inner panel 2A, and then the first mounting robot 5 is retracted.

  In ST3, based on the photographed image of the inner panel 2A, the control device 7 calculates the shift amount of the nut 44B from the pre-teached position as the workpiece attachment position shift amount, which is position information.

  In ST4A, the sunroof member 3 is gripped by the transfer robot 4 at a work supply place (not shown). Then, the transfer of the sunroof member 3 toward the front window opening 41 of the body 2 is started by moving the transfer robot 4.

  In ST5, the first attachment robot 5 is positioned below the conveyed sunroof member 3, and in this state, the first attachment robot 5 is moved until the sunroof member 3 reaches the front window opening 41 of the body 2. The image is moved in synchronism with the operation of the transfer robot 4, and the CCD camera 241 of the first attachment robot 5 is used to photograph the bolt hole 34B of the sunroof member 3 as a reference position.

  In ST6, based on the photographed image of the sunroof member 3, the control device 7 calculates the amount of deviation of the bolt hole 34B from the previously taught position as the workpiece position deviation amount that is position information.

In ST4B, the transfer robot 4 puts the sunroof member 3 into the body 2 through the front window opening 41 of the body 2, and stops the sunroof member 3 below the inner panel 2A.
At this time, the sunroof member 3 is stopped so that the positioning hole 35 of the sunroof member 3 is located immediately below the positioning hole 45 of the body 2 based on the workpiece displacement amount and the workpiece attachment position displacement amount calculated in ST3.

  In ST 7, the first mounting robot 5 is controlled to approach the sunroof member 3 from below, and the positioning pins 223 are inserted into the positioning holes 35 of the sunroof member 3, and both ends of the sunroof member 3 are moved by the first mounting robot 5. Support. As a result, the first attachment robot 5 receives the sunroof member 3 from the transfer robot 4. Here, the operation of the first mounting robot 5 is corrected by reflecting the above-described work position deviation amount in the operation of the first mounting robot 5. Thereafter, the transfer robot 4 is retracted from the inside of the body 2.

In ST8, the first attachment robot 5 is raised to convey the sunroof member 3, and the positioning pins 223 are inserted into the positioning holes 45 of the body 2 to position the sunroof member 3 on the inner panel 2A of the body 2. Here, the operation of the first attachment robot 5 is corrected by reflecting the above-described workpiece attachment position deviation amount and workpiece deviation amount in the operation of the first attachment robot 5.
Then, since the bolt hole 34A of the sunroof member 3 overlaps with the nut 44A of the body 2, the nut runner 23 is driven and the two bolts 51A are passed through the bolt hole 34A of the sunroof member 3 to the nut of the body 2. Tighten to 44A.

In ST9, the remaining bolts 51 except for the bolts 51A are attached to the tightening portion 80 of the second mounting robot 6, and the remaining bolts 51 are passed through the bolt holes 34 of the sunroof member 3 and tightened to the nuts 44.
Here, the operation of the second mounting robot 6 is corrected by reflecting the above-described workpiece displacement amount in the operation of the second mounting robot 6.

According to this embodiment, there are the following effects.
(1) First, the inner panel 2A of the body 2 is photographed by the CCD camera 241 of the first attachment robot 5, and based on this photographed image, the amount of deviation from the position where the inner panel 2A has been previously taught is calculated.
Next, the sunroof member 3 is gripped by the transfer robot 4 at the work supply place, and the sunroof member 3 is transferred and positioned in the vicinity of the inner panel 2A. Simultaneously with the transport of the sunroof member 3, the sunroof member 3 is photographed by the CCD camera 241 of the first mounting robot 5, and the deviation amount of the sunroof member 3 from the previously taught position is calculated based on the photographed image.

  Next, the first mounting robot 5 receives the sunroof member 3 from the transport robot 4, grips and transports the sunroof member 3, positions the sunroof member 3 on the inner panel 2A of the body 2, and then the first mounting robot. The two parts of the sunroof member 3 are temporarily fixed to the inner panel 2A with bolts 51A by the nut runner 23 of the robot 5. Here, the calculated displacement amount of the inner panel 2 </ b> A and the displacement amount of the sunroof member 3 are reflected in the operation of the first attachment robot 5 to correct the operation of the first attachment robot 5.

  Next, the second mounting robot 6 is controlled, and two places of the sunroof member 3 are permanently fixed to the inner panel 2A with bolts 51A by the tightening hand 70 of the second mounting robot 6. Here, the already calculated amount of displacement of the inner panel 2 </ b> A is reflected in the operation of the second mounting robot 6 to correct the operation of the second mounting robot 6.

  Thus, only the positioning and temporary fixing of the sunroof member 3 are performed by the first mounting robot 5, and the sunroof member 3 is permanently fixed by the second mounting robot 6, so that the first mounting robot 5 and the second mounting robot are fixed. The role was shared with 6. Therefore, since each of the first mounting robot 5 and the second mounting robot 6 has an optimum structure according to the role, it is possible to cope with the case where the shape of the sunroof member 3 is different for each model. Cycle time can be shortened.

  (2) The CCD camera 241 of the attachment robot 5 only calculates the displacement amount of the inner panel 2A and the displacement amount of the sunroof member 3 as position information, and based on the calculated position information, the first attachment robot 5 and The operation of the second mounting robot 6 is corrected. Accordingly, it is not necessary to detect the position of the sunroof member 3 and the inner panel 2A of the body 2 many times, so that the number of work steps can be reduced and the cycle time can be further shortened.

  It should be noted that the present invention is not limited to the above-described embodiment, and modifications, improvements, etc. within a scope that can achieve the object of the present invention are included in the present invention.

1 is an overall perspective view of a workpiece mounting system according to an embodiment of the present invention. It is a perspective view of the part to which the sunroof member concerning this embodiment and this sunroof member are attached. It is a top view of the conveyance hand of the conveyance robot which concerns on the said embodiment. It is a perspective view of the conveyance hand concerning the embodiment. It is a top view of the hand of the 1st attachment robot which concerns on the said embodiment. It is a side view of the hand of the 1st attachment robot which concerns on the said embodiment. It is a perspective view of the hand of the 1st attachment robot which concerns on the said embodiment. It is a disassembled perspective view which shows the state which supported the sunroof member with the 1st attachment robot which concerns on the said embodiment. It is a perspective view of the clamping hand of the 2nd attachment robot which concerns on the said embodiment. It is sectional drawing of the clamping hand of the 2nd attachment robot which concerns on the said embodiment. It is a figure for demonstrating operation | movement of the 2nd attachment robot which concerns on the said embodiment. It is a flowchart of operation | movement of the workpiece | work attachment system which concerns on the said embodiment.

Explanation of symbols

1 Work mounting system 2 Body (2nd work)
2A Inner panel (attached part)
3 Sunroof member (first work)
5 First mounting robot (first robot)
6 Second mounting robot (second robot)
7 Controller 23 Nutrunner (Temporary fixing means)
70 Tightening hand (main fixing means)
223 Positioning pin (gripping means)
224 Work support pad (gripping means)
241 CCD camera (position detection means)

Claims (2)

A workpiece mounting system for mounting a first workpiece to the mounted portion of the body from the inside of the body ,
Temporarily fixing means for temporarily fixing the first workpiece to the body, gripping means for gripping a first work, Bei give a position detecting means for detecting the position of the mounting portion of the first workpiece position and the body of the A pair of first robots arranged on the left and right of the body ;
A second robot provided with a main fixing means for main fixing the first work to the body ;
A control device for controlling the first robot and the second robot,
A position information calculating step of calculating, as position information, the position of the first workpiece and the position of the attachment portion of the body from the left and right of the body by the position detection means of the pair of first robots;
Based on the position information calculated in the position information calculation step, the first workpiece is gripped from the left and right inside the body by the gripping means of the pair of first robots , and then the first robot is gripped by the pair of first robots. A positioning step of conveying one workpiece and positioning the first workpiece on the mounted portion of the body ;
A temporary fixing step of temporarily fixing the first workpiece to the body by the temporary fixing means of the pair of first robots;
And a main fixing step of permanently fixing the first work to the body by the main fixing means of the second robot based on the position information calculated in the position information calculating step. . A work mounting method for mounting a first work to a mounted portion of a body from the inside of the body ,
A position information calculation step of calculating, as position information, the position of the first workpiece and the position of the mounted portion of the body from the left and right of the body by a pair of first robots disposed on the left and right of the body ;
Based on the position information calculated in the position information calculation step, the pair of first robots grips the first work from the left and right inside the body , and then the pair of first robots holds the first work. A positioning step of conveying and positioning the first workpiece on the mounted portion of the body ;
A temporary fixing step of temporarily fixing the first workpiece to the body by the pair of first robots;
Based on the position information calculated by the position information calculating step, the workpiece mounting method characterized by and a permanent fixing step of the fixing of the first workpiece in the body by the second robot.

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