JP6688971B2 - Electronic device assembling apparatus and electronic device assembling method - Google Patents

Description

  The present invention relates to an electronic device assembling apparatus and an electronic device assembling method for performing an assembling work for mounting a mounted portion of a cable on a connector.

  In electronic devices such as in-vehicle electronic devices, flexible cables (hereinafter simply referred to as “cables”) such as FPCs that interconnect functional modules such as display devices and circuit boards that configure the devices are often used. Then, in an assembly process of assembling these electronic devices, a connecting work is performed in which the mounted portion of the cable is mounted on the connector to be connected. This connection work has been performed by hand since before, but it is difficult to improve the work efficiency because the connection work for such cables is a complicated work with fine positioning, and this kind of work is difficult. Automation has been proposed (for example, Patent Documents 1 and 2).

  In the prior art shown in Patent Document 1, the work of connecting the connector 3 provided on the cable 1 with a connector to the mating connector 6 provided on the member 5 such as a board is performed by the first robot 10 and the second robot 20. I try to do it with a robot. In the prior art shown in Patent Document 2, the work W1 (flexible cable) is held by a parallel link type robot RB1 and is positioned at a predetermined position / posture by another parallel link type robot RB2 (connector). I am trying to assemble it.

JP 2005-11580 A JP, 2009-50921, A

  By the way, if the electronic device to be connected is a type of electronic device that is used in an environment with shock or vibration, such as an in-vehicle electronic device, prevent the connection part from loosening or coming off due to shock or vibration. In order to ensure the reliability of the connection part, a connector with a lock mechanism is often used. Then, in the connection work, the attached part of the cable is attached to the connector with the lock cover opened in advance and the lock mechanism is released, and then the lock cover is closed to lock the attached part. There is.

  However, in the prior art including the prior art shown in the above-mentioned patent document examples, even when such a connector with a lock mechanism is used, it can be said that the reliability of the connection state after the mounting is always ensured. It was difficult. That is, in the prior art, there is no way to confirm whether or not the connection work is being performed in the state where the function of the lock mechanism is properly operated, and the connection work is performed while the mounted part is not completely locked to the connector. We couldn't rule out the occurrence of the situation that finished the process.

  Therefore, it is an object of the present invention to provide an electronic device assembling apparatus and an electronic device assembling method capable of ensuring the reliability of the connection state after mounting when a cable is mounted on a connector with a lock mechanism.

An electronic device assembling apparatus according to the present invention includes a cable mounting mechanism that holds a cable and mounts a mounted part of the cable on a connector of an electronic device, a lock operating mechanism that operates a lock mechanism included in the connector, and the connector. A lock state confirmation unit for confirming the state of the lock mechanism, and a control unit for controlling the cable mounting mechanism and the lock actuation mechanism, and the control unit is A cable mounting mechanism for mounting the cable on the connector, further comprising a base portion having the cable mounting mechanism and the lock operating mechanism, the cable mounting mechanism including a cable holding tool for holding the cable; The lock actuating mechanism includes a connector locking tool for actuating the lock mechanism, and the base portion includes the connector lock tool. And Buru holding tool and the connector locking tool Ru are mounted to face each other.

An electronic device assembling method according to the present invention is an electronic device assembling method for mounting an attached part of a cable to a connector of an electronic device by using the electronic device assembling apparatus according to claim 1. When the state confirmation unit confirms the state of the lock mechanism provided in the connector with no cable attached, and when the lock state confirmation unit determines that the lock state is the open state, the cable attachment mechanism attaches the cable to the connector and actuates said locking mechanism by actuating the lock actuating mechanism, the lock status checking unit confirms the status of the locking mechanism of the connector where the cable is attached.

  ADVANTAGE OF THE INVENTION According to this invention, when attaching a cable to the connector with a lock mechanism, the reliability of the connection state after attachment can be ensured.

1 is a perspective view of an electronic device assembling apparatus according to an embodiment of the present invention. Structure explanatory drawing of the head part incorporated in the robot part of the electronic device assembly apparatus of one embodiment of this invention 1 is a perspective view of an electronic device (before a cable is attached) which is a work target of an electronic device assembling apparatus according to an embodiment of the present invention. 1 is a perspective view of an electronic device (after a cable is attached) which is a work target of an electronic device assembling apparatus according to an embodiment of the present invention. Structure explanatory drawing of the cable used as the work target of the electronic device assembly apparatus of one embodiment of this invention Structure explanatory drawing of the cable used as the work target of the electronic device assembly apparatus of one embodiment of this invention Structure explanatory drawing of the chuck block in the cable holding tool of the electronic device assembly apparatus of one embodiment of this invention Functional explanatory drawing of the chuck block in the cable holding tool of the electronic device assembly apparatus of one embodiment of the present invention Functional explanatory drawing of the chuck block in the cable holding tool of the electronic device assembly apparatus of one embodiment of the present invention 1 is a block diagram showing a configuration of a control system of an electronic device assembling apparatus according to an embodiment of the present invention. The flowchart which shows the cable mounting operation | movement in the electronic device assembling method of one embodiment of this invention. Explanatory drawing of the state confirmation of the connector in the electronic device assembling method of one embodiment of the present invention Explanatory drawing of the state confirmation of the connector in the electronic device assembling method of one embodiment of the present invention Operation explanatory view of holding and positioning of a cable in an electronic device assembling method according to an embodiment of the present invention Explanatory drawing of the image for position recognition of a connector and a cable in the electronic device assembling method of one embodiment of the present invention. Explanatory drawing of the mounting operation to the connector of the cable in the electronic device assembling method of one embodiment of this invention. Explanatory drawing of the operation | movement operation of the lock mechanism of the connector in the electronic device assembling method of one embodiment of this invention. Structure explanatory drawing of the cable (1st modification) used as the work target of the electronic device assembly apparatus of one embodiment of this invention. Structure explanatory drawing of the cable (2nd modification) used as the work target of the electronic device assembly apparatus of one embodiment of this invention. Functional explanatory drawing of the cable holding tool (1st modification) of the electronic device assembly apparatus of one embodiment of this invention. Structure explanatory drawing by the cable holding tool (1st modification) of the electronic device assembly apparatus of one embodiment of this invention. Structure explanatory drawing of the cable holding tool (2nd modification) of the electronic device assembly apparatus of one embodiment of this invention. Functional explanatory drawing of the cable holding tool (2nd modification) of the electronic device assembly apparatus of one embodiment of this invention.

  Next, embodiments of the present invention will be described with reference to the drawings. First, the overall configuration of the electronic device assembling apparatus 1 will be described with reference to FIG. The electronic device assembly apparatus 1 targets an electronic device 4 (see FIGS. 3 and 4) such as an on-vehicle electronic device as a work target, and connects functional modules such as a circuit board and a display device to each other by a cable such as a flexible printed circuit board. That is, the electronic device assembling apparatus 1 has a function of mounting the mounted portion of the cable which is connected in advance to the display device or the like to the connector of the circuit board.

  In FIG. 1, a work stage 3 is provided on an upper surface 2 a of a base 2, and the work stage 3 positions and holds an electronic device 4 as a work target. Here, the electronic device 4 as a work target will be described with reference to FIGS. 3 and 4. 3 shows a state before the cable is attached to the connector, and FIG. 4 shows a state where the cable is attached to the connector.

  In FIG. 3, an electronic device 4 is a vehicle-mounted electronic device having a display device such as a meter on a dashboard, a navigation device, a room mirror, and various controllers, and mainly includes a circuit board 11 on which an electronic component 11a is mounted and a display device 12. I am trying. 3 and 4 show a state where the display device 12 is placed with the display surface facing downward.

  Both the circuit board 11 and the display device 12 have a rectangular shape, and the circuit board 11 and the display device 12 are provided on a plurality of sides (here, two short sides and one long side, which are three sides) of the display device 12. A cable 17 for electrically connecting 12 and 12 is connected in advance. In the present embodiment, the cable 17 has a configuration in which a reinforcing plate 16 for handling is preliminarily joined to one end 15a (see FIG. 5) of the cable main body 15 such as a flexible printed circuit board.

  On the edges of the mounting surface of the circuit board 11 corresponding to the plurality of sides to which the cables 17 are connected in the display device 12, the attached portions 15b formed at one end portions 15a of the respective cable body portions 15 are attached. A connector 13 is provided. In the connector 13, a terminal row for connection is formed on the terminal surface 13b (see FIG. 13) on the bottom surface of the mounting portion 13a to which the mounting portion 15b is mounted. In the mounted state, the wiring pattern 15d (see FIG. 5) formed on the mounted portion 15b contacts these terminal rows.

  The connector 13 includes a lock mechanism having a cover member 14 for preventing the mounted portion 15b from falling off. The cover member 14 is provided so as to be openable and closable with respect to the connector 13, and in a state in which the electronic device 4 is carried into the work stage 3 before the attached portion 15b is attached to the connector 13, as shown in FIG. The member 14 is in an upright open state. As shown in FIG. 4, when the mounted portion 15b is mounted on the connector 13 and the lock mechanism is operated, the cover member 14 is pushed down to the closed state, and the mounted portion 15b is pressed to prevent the cover member 14 from falling off. .

  In FIG. 1, the work stage 3 can be moved up and down and rotated in a horizontal plane. When mounting the cable 17 for the electronic device 4, the work stage 3 is moved up and down to move the electronic device. Position 4 at the desired working height. Further, by rotating the work stage 3, the side of the electronic device 4 on which the cable 17 to be worked is provided is aligned with a predetermined work position by the robot unit 5 described below.

  A corner post 2b is erected on a corner portion of an upper surface 2a of the base 2, and a horizontal pedestal 2c is erected on an upper end portion of the corner post 2b. An operation panel 10 having a touch panel is arranged on the side surface of the gantry 2c. An instruction input for an operation or an operation instruction for the robot unit 5 is executed by a touch operation input via the operation panel 10. The operation panel 10 has a display function, and a notification when an abnormality or a defect occurs in the cable mounting operation by the electronic device assembling apparatus 1 is displayed on the operation panel 10. As for the coordinate system of the electronic device assembling apparatus 1, when viewed from the front of the electronic device assembling apparatus, the horizontal direction is the X-axis, the axis orthogonal to the X-axis is the Y-axis, the X-axis, and the Y-axis are vertical. The axis orthogonal to the direction is the Z axis.

  A fixed base portion 6 incorporating a drive mechanism for the robot portion 5 described below is provided on the lower surface of the gantry 2c. Six servo drive mechanisms that operate individually are built in the fixed base portion 6, and each servo drive mechanism individually drives six link members 7 extending downward from the fixed base portion 6. The lower end portion of the link member 7 is joined to the base portion 8. In the above structure, the fixed base portion 6, the link member 7, and the base portion 8 form the robot portion 5.

  Here, the robot unit 5 is a 6-degree-of-freedom parallel link robot having six link members 7 that operate individually, and the lower ends of the six link members 7 extending downward from the fixed base unit 6 are The head portion 9 which is a working unit for performing the mounting work for mounting the cable 17 on the connector 13 is coupled to the base portion 8. As shown in FIG. 2, the link member 7 is coupled to the base portion 8 through the universal joint 7a, and with this configuration, the robot portion 5 can cause the base portion 8 to perform a movement operation of 6 degrees of freedom. Has become.

  The cable holding tool 20 and the connector lock tool 30 are attached to the base portion 8, and further include an image pickup portion 40 and an illumination 46. The cable holding tool 20 has a function of holding the cable 17 to be attached to the connector 13, and the connector lock tool 30 has a function of operating a lock mechanism provided in the connector 13, that is, the attached portion 15b. It has a function of pushing down the cover member 14 in the connector 13 in a state of being attached to bring it into a closed state.

  By moving the base unit 8 by the robot unit 5, the cable holding tool 20 and the connector lock tool 30 can be moved relative to the electronic device 4 held on the work stage 3. In the mounting work for mounting the mounted portion 15b of the cable 17 to the connector 13, the robot unit 5, the cable holding tool 20, and the connector lock tool 30 are operated by the control unit 51 (see FIG. 10).

  The robot unit 5 and the cable holding tool 20 constitute a cable mounting mechanism that holds the cable 17 and mounts it on the connector 13. The robot unit 5 and the connector lock tool 30 form a lock operating mechanism that operates the lock mechanism provided in the connector 13. In the present embodiment, the configuration in which the cable holding tool 20 and the connector lock tool 30 are moved by the common robot unit 5 has been shown, but the configuration in which the cable holding tool 20 and the connector lock tool 30 are moved by separate drive mechanisms. May be

  The detailed configuration of the cable holding tool 20 will be described. In the base portion 8 shown in FIG. 2, an opening 8a is provided at the drive center indicating the center position of the plurality of universal joints 7a. A guide rail 21 is arranged in the Y direction on the lower surface near the side end portion, which is separated from the opening 8a in the right direction. A moving block 22 is fixed to a slider 21a slidably mounted on the guide rail 21, and the moving block 22 can move back and forth in the Y direction (arrow a).

  The screw portion 22a extending from the right end surface of the moving block 22 penetrates through a through hole provided in the side end member 8b extending from the outer end surface of the base portion 8, and the screw portion 22a has a side end. A nut member 22b is screw-fitted to the outside of the member 8b. A spring member 23, which is a tension spring, is connected to the left end surface of the moving block 22, and the spring member 23 biases the moving block 22 toward the drive center of the base portion 8. In this configuration, the nut member 22b functions as a stopper that regulates the stop position of the moving block 22 that is biased toward the drive center side, and by adjusting the position of the nut member 22b, the cable having the configuration described below is formed. The relative position of the holding tool 20 with respect to the base portion 8 can be adjusted.

  A chuck base 24 that extends obliquely downward toward the drive center side of the base portion 8 is coupled to the moving block 22. An actuator 25 having a slide portion 26 that advances and retracts (arrow b) toward the drive center side is arranged on the upper surface side of the chuck base 24. Further, a blade 28, which is a thin plate member having a tapered portion at its tip, is horizontally mounted on the lower end of the chuck base 24. The position of the blade 28 is set so that its tip is located below the opening 8a, and the position of the blade 28 can be adjusted by adjusting the position of the nut member 22b in the screw portion 22a. It is like this.

  The biasing force of the spring member 23 acts as a cushioning force for the blade 28. That is, in the process of operating the robot unit 5 to move the base unit 8, when the tip of the blade 28 contacts the electronic device 4 or the like, the spring member 23 extends to move the entire cable holding tool 20. As a result, a cushioning function is provided to prevent an excessive external force from acting on the blade 28.

  A chuck block 27 having a trapezoidal side cross section is joined to the end surface of the slide portion 26 on the advancing side. When the actuator 25 is operated and the chuck block 27 is advanced obliquely downward, the chuck surface 27 a (see FIG. 7) of the chuck block 27 contacts the blade 28. In this embodiment, when the cable 17 is held by the cable holding tool 20, the cable 17 is held by sandwiching the reinforcing plate 16 between the blade 28 and the chuck surface 27a of the chuck block 27 from above and below. There is.

  Next, the configuration of the connector lock tool 30 will be described. In FIG. 2, a bracket 31 extending obliquely upward in the outer direction is fixed to the lower surface of the base portion 8 on the left end side. An actuator 32 having a rod 32a that moves forward and backward (arrow c) toward the drive center side of the base portion 8 is attached to the bracket 31. Further, the buffer portion 33 coupled to the rod 32a is provided with a roller holding portion 34 having a tip end portion to which a roller 35 as an abutting portion is attached. By driving the actuator 32, the roller holding portion 34 advances toward the drive center side via the buffer portion 33, whereby the roller 35 abuts the cover member 14 of the connector 13 and operates the lock mechanism (see FIG. 17). ). That is, the connector lock tool 30 includes an actuator 32 that causes the roller 35 as an abutting portion that abuts the lock mechanism included in the connector 13 to move forward and backward. The roller 35 is configured to move forward and backward obliquely by the actuator 32, and to come closest to the cable holding tool 20 in a state where the roller 35 advances obliquely downward (see FIG. 17).

  Here, the buffer portion 33 holds the roller holding portion 34 in a state in which the roller holding portion 34 is allowed to rotate around the holding shaft 33a and is biased in a direction of pressing the roller 35 downward. As a result, in the operation of moving the roller 35 forward and backward by the actuator 32, the shock when the roller 35 abuts the cover member 14 is alleviated by the function of the buffer portion 33. That is, the connector lock tool 30 is configured to include the cushioning portion 33 that absorbs an impact when the roller 35, which is the contact portion, contacts the cover member 14 of the lock mechanism included in the connector 13.

  An image pickup section 40 including an optical lens section 42 and a camera 43 is arranged in a bracket 41 standing upright on the upper surface of the base section 8 in the vicinity of the opening section 8a in a downward posture with an image pickup optical axis 43a as a driving center. Has been done. The robot unit 5 is operated so that the head unit 9 is positioned above the electronic device 4 held by the work stage 3 and an image is picked up by the image pickup unit 40, whereby the cable 17 held by the cable holding tool 20 is picked up. It is possible to acquire the image of the mounted portion 15b and the image of the connector 13 mounted on the circuit board 11.

  A support member 44 is erected downward on the lower surface side of the base portion 8 so as to surround the opening 8a. An illumination holding plate 45 corresponding to the outer shape of the electronic device 4 is held at the lower end of the support member 44, and an illumination 46 made of a light emitting body such as an LED is attached to the lower surface of the illumination holding plate 45. . When the image is captured by the image capturing unit 40, the illumination 46 is turned on to illuminate the cable 17 and the connector 13 which are the image capturing targets. That is, the base portion 8 of the head portion 9 is configured to include the image pickup portion 40 that detects the mounted portion 15b of the cable 17 and the illumination 46. The cable holding tool 20 and the connector lock tool 30 are arranged so as to face each other with the imaging optical axis 43a of the camera 43 of the imaging unit 40 interposed therebetween. With such an arrangement, it is possible to image both the cable 17 held by the cable holding tool 20 by the common imaging unit 40 and the connector 13 to be locked by the connector lock tool 30.

  Further, a distance measuring sensor 47 is arranged on the lower surface of the base portion 8 near the connector lock tool 30 side at the periphery of the opening 8a with the measurement optical axis 47a facing downward. The distance measurement sensor 47 measures the distance from the measurement target surface of the measurement target object located on the measurement optical axis 47a to the measurement reference position of the distance measurement sensor 47, in other words, the height position of the measurement target surface. In the present embodiment, the distance measuring sensor 47 is positioned above the connector 13, and the height of a predetermined position of the connector 13 is measured by the distance measuring sensor 47 to lock the lock mechanism of the connector 13. I try to confirm the condition.

  Next, the configuration of the cable 17 will be described in detail with reference to FIG. As shown in FIGS. 5A and 5B, the cable 17 has a strip-shaped cable main body 15 in which an attached portion 15b to be attached to the connector 13 is formed at one end 15a, and the cable main body 15 The reinforcing plate 16 joined to the one end portion 15a side of the one surface 15c via the joint portion 17a. The opposite side of the one side 15c to which the reinforcing plate 16 is joined in the cable main body 15 is a pattern forming surface on which the wiring pattern 15d is formed, and when the cable 17 is attached to the connector 13, the attached portion 15b is attached. The wiring pattern 15d is pressed against the terminal surface 13b formed on the mounting portion 13a of the connector 13 to be brought into contact therewith. As a result, the cable body 15 of the cable 17 is electrically connected to the connector 13.

  As shown in FIG. 5B, the portion (free end portion 16a) located on the opposite side of the one end portion 15a to the joint portion 17a joined to the one surface 15c of the cable body portion 15 in the reinforcing plate 16 is An opening portion 17b is formed apart from the one surface 15c of the cable body portion 15. In the present embodiment, when the cable 17 is held by the cable holding tool 20 shown in FIG. 2, the blade 28 is inserted into the opening portion 17b so that the reinforcing plate 16 is held between the chuck block 27 and the chuck block 27. (See FIG. 8).

  When the cable 17 having the above-described configuration is targeted, the cable holding tool 20 holds the cable 17 by sandwiching and holding the reinforcing plate 16. That is, the cable holding tool 20 shown in the present embodiment is a chuck mechanism that sandwiches the reinforcing plate 16 from the vertical direction. The chuck mechanism abuts on the blade 28 inserted into the opening portion 17b between the cable main body 15 and the reinforcing plate 16 and the reinforcing plate 16 located on the upper surface of the blade 28 and presses it downward. And a block 27.

  FIG. 6 shows a modification of the cable 17 shown in FIG. That is, in the cable 17, the joining portion 17a for joining the reinforcing plate 16 is set at a position that does not overlap the mounted portion 15b provided on the one end portion 15a side, but in the cable 17A shown in FIG. The joint portion 17a is set at a position overlapping the mounted portion 15b. In this example, when the cable 17A is attached to the connector 13, not only the attached portion 15b but also the reinforcing plate 16 overlapping the attached portion 15b is attached to the connector 13.

  Also in this modified example, similarly to the cable 17 shown in FIG. 5, a portion (free portion) located on the opposite side of the one end portion 15a with respect to the joint portion 17a joined to the one surface 15c of the cable body portion 15 in the reinforcing plate 16. The end portion 16a) is formed with an opening portion 17b which is separated from the one surface 15c of the cable body portion 15. When the cable 17 is held by the cable holding tool 20, similarly, the blade 28 is inserted into the opening portion 17b and the reinforcing plate 16 is held between the chuck block 27 and the chuck block 27 (see FIG. 9).

  Next, with reference to FIG. 7, the details of the chuck block 27 provided in the cable holding tool 20 and used in the chuck mechanism for sandwiching the reinforcing plate 16 will be described. FIG. 7A shows a state in which the chuck block 27 is separated from the blade 28, and a plurality of spike claws 27b are provided on the chuck surface 27a of the chuck block 27 in a protruding manner. In the chuck state in which the reinforcing plate 16 is sandwiched between the blade 28 and the chuck surface 27a, the spike claw 27b slightly bites into the surface of the reinforcing plate 16 to prevent the sandwiched reinforcing plate 16 from slipping off. To prevent. That is, in the cable holding tool 20, the chuck surface 27a of the chuck block 27 that abuts the reinforcing plate 16 is formed with a slip stopper. The slip stopper is not limited to the spike claw 27b, and various methods such as roughening the chuck surface 27a can be used.

  FIG. 7B shows a state in which the actuator 25 (see FIG. 2) is driven to lower the chuck block 27 along the chuck base 24 (arrow d), and the chuck surface 27 a is brought close to the blade 28 and closed. ing. In this state, the sizes of the chuck block 27 and the blade 28 are set so that a protruding portion protruding from the tip of the blade 28 by a predetermined width B is formed at the tip of the chuck surface 27a. By setting the size of the chuck block 27 in the cable holding tool 20 in this manner, as shown in FIGS. 8 and 9, the effect of correcting the deformation of the cables 17 and 17A in the state of being held by the cable holding tool 20 can be obtained. obtain.

  FIG. 8A shows a case where the cable 17 shown in FIG. 5 is a holding target. As shown in FIG. 8A, in the cable 17 having the configuration in which the reinforcing plate 16 is joined to the cable body 15 with the attached portion 15b protruding from the one end 15a of the cable body 15, When the blade 28 is inserted into the opening portion 17b between the reinforcing plate 16 and the reinforcing plate 16, the one end portion 15a formed with the mounted portion 15b is deformed into a warp shape or a wavy shape in the width direction. There is.

  Even in such a case, as shown in FIG. 8B, the chuck block 27 is brought close to the blade 28 (arrow e), and the reinforcing plate 16 is provided between the chuck surface 27 a and the blade 28. In the sandwiched state, the chuck surface 27a of the chuck block 27 projects to at least the upper surface of the joint portion 17a that joins the cable body portion 15 and the reinforcing plate 16 when the reinforcing plate 16 is sandwiched. As a result, the above-mentioned deformation is corrected in the portion near the one end 15a of the cable main body 15 by following the chuck surface 27a having a planar shape.

  Similarly, when the cable 17A shown in FIG. 6 is set as a holding target, the same effect is obtained. That is, as shown in FIG. 9A, in the cable 17A having a structure in which the reinforcing plate 16 is joined to the cable body 15 with the attached portion 15b and the joining portion 17a being overlapped at the one end 15a of the cable body 15. Also, when the blade 28 is inserted in the opening portion 17b between the cable body portion 15 and the reinforcing plate 16, the one end portion 15a where the attached portion 15b is formed has a warped shape or a wavy shape in the width direction. Deformation may occur.

  Even in such a case, as shown in FIG. 9B, the chuck block 27 is brought close to the blade 28 (arrow f), and the reinforcing plate 16 is provided between the chuck surface 27 a and the blade 28. In the sandwiched state, the chuck surface 27a of the chuck block 27 projects to at least the upper surface of the joint portion 17a that joins the cable body portion 15 and the reinforcing plate 16 when the reinforcing plate 16 is sandwiched. As a result, the above-mentioned deformation is corrected in the portion near the one end 15a of the cable main body 15 by following the chuck surface 27a having a planar shape.

  Next, the configuration of the control system of the electronic device assembling apparatus 1 will be described with reference to FIG. 10, the control unit 51 includes a robot unit 5, a work stage 3, an imaging unit 40, an illumination 46, a distance measuring sensor 47, an actuator 25 (cable holding tool 20), an actuator 32 (connector lock tool 30), and an operation panel 10. , Is connected to the notification unit 55.

  The control unit 51 controls the robot unit 5, the work stage 3, the actuator 25 of the cable holding tool 20, and the actuator 32 of the connector lock tool 30 to execute the cable mounting operation shown in FIG. 11. That is, in the control process described above, the control unit 51 operates the robot unit 5, the cable holding tool 20, and the connector lock tool 30 to execute a cable mounting operation for mounting the mounted portion 15b of the cable 17 to the connector 13. . In other words, the control unit 51 controls the cable mounting mechanism including the cable holding tool 20 and the robot unit 5, and the lock operating mechanism including the connector lock tool 30 and the robot unit 5.

  In the process of executing this cable mounting operation, the control unit 51 controls the imaging unit 40 and the illumination 46 to execute the imaging process for detecting the positions of the mounted part 15b of the cable 17 and the connector 13, and also the distance measurement. The sensor 47 is controlled to execute the distance measurement process for confirming the locked state of the connector 13. Operation commands for executing these processes are input via the operation panel 10, and the control unit 51 executes predetermined control processes accordingly. The notification unit 55 performs a process of displaying a notification on the operation panel 10 when an abnormality or a defect occurs in the process of executing the cable mounting operation by the electronic device assembly apparatus 1.

  Further, the control unit 51 includes a cable position detection unit 52, a connector position detection unit 53, and a lock state determination unit 54 as internal control processing functions. The cable position detection unit 52 detects the position of the attached portion 15b based on the recognition screen obtained by capturing the attached portion 15b of the cable 17 held by the cable holding tool 20 with the image capturing unit 40. Similarly, the connector position detection unit 53 detects the position of the connector 13 based on the recognition screen obtained by capturing the image of the connector 13 to be mounted by the image capturing unit 40. In the cable mounting operation for mounting the mounted portion 15b on the connector 13, the control unit 51 controls the movement of the cable holding tool 20 by the robot unit 5 based on the position detection results of the mounted portion 15b and the connector 13.

  The lock state determination unit 54 performs a process of determining the state of the lock mechanism included in the connector 13 based on the measurement result of the distance measurement sensor 47 for the connector 13 or the image of the connector 13 captured by the image capturing unit 40. To do. The lock state determination unit 54, the distance measurement sensor 47, the lock state determination unit 54, and the imaging unit 40 configure a lock state confirmation unit that confirms the state of the lock mechanism included in the connector 13. In the electronic device assembling apparatus 1 according to the present embodiment, the following two forms exist as the lock state confirming unit, and one of them is selected and used.

  First, in the first embodiment, the lock state confirmation unit measures the height of a portion where the height changes depending on the state of the lock mechanism provided in the connector 13, that is, the open / closed state of the cover member 14 forming the lock mechanism. The sensor 47 and the lock state determination unit 54 that determines the state of the lock mechanism based on the measurement result of the distance measurement sensor 47 are provided. In the second mode, the lock state confirmation unit determines the state of the lock mechanism included in the connector 13 based on the image capturing unit 40 capable of capturing the image of the connector 13 and the image captured by the image capturing unit 40. And 54.

  In any of the above-described modes, the lock state confirmation unit confirms the state of the lock mechanism of the connector 13 before the attached portion 15b of the cable 17 is attached, and as a result of the confirmation, the lock mechanism is functioning or When it is determined that the work of mounting the mounted portion 15b is hindered, the control unit 51 stops the mounting work of the mounted portion 15b of the cable 17 to the connector 13 and causes the notification unit 55 to notify the operator. I am trying to inform that fact. Further, the lock state confirmation unit confirms the state of the lock mechanism of the connector 13 to which the attached portion 15b of the cable 17 is attached, and as a result of the confirmation, determines that the lock mechanism is not in a sufficiently functioning state. First, the control unit 51 informs the operator by the notifying unit 55.

  Next, referring to the flow of FIG. 11 and each drawing, the cable mounting operation executed by the electronic device assembly apparatus 1, that is, the mounted portions 15b of the cables 17 and 17A shown in FIGS. A method of assembling the electronic device mounted on the device 13 will be described. In the electronic device assembling method shown here, a strip-shaped cable main body 15 having an attached portion 15b formed at one end 15a, and a reinforcing plate 16 joined to the one end 15a side on one surface 15c of the cable main body 15 are provided. The cables 17 and 17A having the 12 and the following figures, only the cable 17 is shown and only the cable 17 is shown in the description, but the same applies when the cable 17A is targeted.

  Further, in the cable 17, a mouth opening portion 17b separated from the one surface 15c is formed in a portion of the reinforcing plate 16 located on the opposite side of the one end portion 15a with respect to the joint portion 17a joined to the one surface 15c of the cable body portion 15. The cable holding tool 20 holds the reinforcing plate 16 to carry out the cable mounting operation.

  The connector 13 that is the target of the cable mounting operation includes a lock mechanism that prevents the mounted portion 15b that has been mounted from falling off. This lock mechanism has a structure including a cover member 14 (see FIG. 13) that rotates around a holding shaft 14a to perform an opening / closing operation, and by pushing down the cover member 14 in an open state by a connector lock tool 30. , This lock mechanism is activated.

  When starting the cable mounting operation, first, the lock state confirmation unit included in the electronic device assembling apparatus 1 confirms the lock state (ST1). In the confirmation of the locked state, first, the robot unit 5 is operated to move the head unit 9, and as shown in FIG. 12, the distance measuring sensor 47 is positioned above the connector 13 to be worked, and the measurement optical axis is set. The alignment is performed so that 47a matches the measurement target position of the connector 13. At this time, at the position corresponding to the connector 13 of the work target in the electronic device 4, the cable 17 in which the cable main body portion 15 is connected to the display device 12 (see FIG. 3) in advance has the attached portion 15b directed upward. It is located in a posture.

  The confirmation of the state of the lock mechanism by the lock state confirmation unit is made by measuring the height of a portion where the height changes depending on the state of the lock mechanism. Here, as the position where the height changes, as illustrated in FIG. 13, the (A) position (the upper surface 13c of the connector 13), the (B) position (the upper end portion of the cover member 14 in the open state), and the (C) position. Two of (the terminal surface 13b of the mounting portion 13a of the connector 13) are selected and used.

  For example, the heights of the A position and the B position are measured by the distance measuring sensor 47, and the difference in height between these two positions is calculated. If the height difference is equal to or greater than a predetermined value, the cover member 14 is normally opened. It is determined that the lock mechanism is in the released state. It should be noted that instead of the (B) position, the (C) position is the height measurement target, and the heights of the A position and the C position are measured by the distance measurement sensor 47, and based on the heights of these two positions, Similarly, the state of the lock mechanism may be determined. The lock state confirmation unit may confirm the state of the lock mechanism based on the image of the connector 13 captured by the image capturing unit 40. In this case, the state of the lock member, that is, the state of the cover member 14 in the connector 13, determines whether or not the cover member 14 is in the open state.

  Then, in the confirmation of the locked state in (ST1), when it is confirmed that the open state is insufficient, the control unit 51 informs the fact by the notifying unit 55 (ST2). That is, the state of the lock mechanism of the connector 13 to which the cables 17 and 17A are not attached is such that the cover member 14 is closed and the lock mechanism is functioning, or the cover member 14 is opened halfway. When it is determined that the work of mounting the cables 17 and 17A is hindered, the cable mounting mechanism including the robot unit 5 and the cable holding tool 20 stops the work of mounting the cables 17 and 17A to the connector 13. The notification unit 55 notifies the operator to that effect. As a result, it is possible to prevent a malfunction such as a mounting error due to the cable mounting operation being performed on the connector 13 in an abnormal state.

  Next, the cable 17 is held by the cable holding tool 20 (ST3). The cable holding tool 20 used here includes a blade 28 that is inserted into the opening 17b between the cable body 15 and the reinforcing plate 16 and a chuck that presses the reinforcing plate 16 located on the upper surface of the blade 28 downward. It has a configuration including a block 27. In the holding operation of the cable 17, as shown in FIG. 14A, the robot unit 5 causes the cable holding tool 20 to perform a scooping operation (arrow g). As a result, the blade 28 is inserted into the opening portion 17b between the cable body portion 15 and the reinforcing plate 16 of the cable 17 which is connected to the electronic device 4 in advance (arrow h), and the upper surface of the blade 28 is attached to the reinforcing plate. Hold in contact with 16.

  Then, after that, the actuator 25 is driven to bring the chuck block 27 closer to the blade 28 (arrow i), and the reinforcing plate 16 is sandwiched and held between the blade 28 and the chuck surface 27 a of the chuck block 27. That is, when holding the cable 17 during the cable mounting operation, the reinforcing plate 16 is held by the cable holding tool 20. When the reinforcing plate 16 is held by the cable holding tool 20, since the spike claw 27b (see FIG. 7) as a slip stopper is formed on the chuck surface 27a of the chuck block 27, the reinforcing plate 16 slips off. This can be prevented and the cable 17 can be stably held.

  Further, since the chuck surface 27a of the chuck block 27 projects from the tip of the blade 28, the cable main body 15 to which the cable body 15 is attached is extended from the reinforcing plate 16 sandwiched between the blade 28 and the chuck surface 27a. The deformation of the portion 15b is corrected by following the planar chuck surface 27a (see FIG. 8). This makes it possible to prevent problems due to deformation in the image pickup of the attached portion 15b and the attachment to the connector 13 described below.

  After that, temporary cable positioning is performed (ST4). Here, the attached portion 15b of the cable 17 held by the cable holding tool 20 is provisionally positioned with respect to the connector 13 for position detection imaging (ST4). That is, as shown in FIG. 14B, the cable is placed so that the mounted portion 15b approaches the connector 13 in a horizontal posture, and the mounted portion 15b is positioned together with the connector 13 within the focal range FZ in the imaging by the imaging unit 40. Align the holding tool 20.

  Then, in this state, the connector 13 and the cable 17 which are the objects of the mounting work are imaged and recognized by the imaging unit 40 (ST5). That is, the image of the mounted portion 15b and the connector 13 temporarily positioned in (ST4) is acquired by the camera 43 of the imaging unit 40, and the relative positional relationship between the mounted portion 15b and the connector 13 is obtained based on this image. Recognition processing is performed.

  FIG. 15 shows the recognition image 40a that is obtained in (ST5) and is the target of the recognition process. That is, in the recognition image 40a, the chuck block of the cable holding tool 20 holding the cable 17 attached to the connector 13 together with the image of the connector 13 before the cable attachment in which the cover member 14 constituting the lock mechanism is opened. An image in which the tip of 27 is viewed in plan appears. In the recognition image 40a, since the positional relationship between the imaging unit 40 and the cable holding tool 20 is fixed, the chuck block 27 always appears at the fixed position that matches the image frame direction.

  On the other hand, the reinforcing plate 16 and the mounted portion 15b, which are held by being sandwiched between the chuck block 27 and the blade 28, show some positional deviation due to the positional error in the holding operation shown in FIG. . Further, the connector 13 is also in a position shift state due to a position holding error of the electronic device 4 on the work stage 3, a position error of the connector 13 on the electronic device 4, and the like. That is, the relative positional relationship between the connector 13 and the mounted portion 15b mounted on the connector 13 varies depending on the connector 13 that is the mounting work target.

  Therefore, when the mounted portion 15b is inserted into the mounting portion 13a of the connector 13 and mounted, position correction data for correcting such variation in relative positional relationship is acquired from the recognition image 40a shown in FIG. . That is, the positions of the recognition points R1 and R2 for detecting the position of the mounted portion 15b are obtained, and the midpoint of the recognition points R1 and R2 is set as the representative point PM1 indicating the position of the mounted portion 15b. Further, the positions of the recognition points R3, R4, R5 for detecting the position of the connector 13 are obtained, and the middle point of the recognition points R4, R5 is set as the representative point PM2 indicating the position of the connector 13.

  Then, the cable 17 is attached to the connector 13 (ST6). In this mounting operation, the cable holding tool 20 holding the cable 17 is aligned so that the respective representative points PM1 and PM2 have an appropriate positional relationship. That is, as shown in FIG. 16A, the cable holding tool 20 is moved (arrow j) so that the tip of the mounted portion 15b of the cable 17 is slanted to the mounting portion 13a of the connector 13 of the electronic device 4 in a slightly oblique direction. Insert from. At this time, the cover member 14 is in an upright open state and does not hinder the insertion of the mounted portion 15b.

  When the attached portion 15b of the cable 17 is attached to the terminal surface 13b of the connector 13 of the electronic device 4, based on the relative positional relationship between the attached portion 15b and the connector 13 obtained in (ST5), Control the movement of the cable holding tool 20. Next, as shown in FIG. 16B, the posture of the cable holding tool 20 is adjusted (arrow k) so that the mounted portion 15b is in a horizontal posture, and the mounted portion 15b is formed on the terminal surface 13b of the connector 13. The wiring pattern 15d is brought into contact with the terminal surface 13b.

  After this, connector locking is executed (ST7). Here, the lock mechanism provided in the connector 13 is operated by the connector lock tool 30. That is, as shown in FIG. 17A, first, the chuck block 27 in the cable holding tool 20 is lifted to release the chucked state of the reinforcing plate 16. Next, in the connector lock tool 30, the actuator 32 (see FIG. 2) is operated to cause the rod 32a and the buffer portion 33 connected to the rod 32a to project (arrow m). As a result, the roller 35 at the tip of the roller holding portion 34 mounted on the buffer portion 33 moves to the upper surface side of the connector 13 and contacts the cover member 14 while rolling on the upper surface of the connector 13 and pushes it down.

  At this time, the roller holding portion 34 is rotatably held by the buffer portion 33 via the holding shaft 33a and is urged downward. When the roller 35 contacts the connector 13 and the cover member 14, the holding shaft is held. By rotating around 33a in the direction of arrow n, the impact when the roller 35 contacts the connector 13 and the cover member 14 is alleviated.

  Then, the robot unit 5 is operated to move the base unit 8 to the right (arrow o), so that the roller 35 rolls on the upper surface of the connector 13 and the cover member 14 is moved as shown in FIG. 17B. Push down to close. As a result, the cover member 14 presses the mounted portion 15b, the lock mechanism of the connector 13 operates, and the mounted portion 15b is prevented from falling off. At the same time, in the cable holding tool 20, the blade 28 separates from between the lower surface of the reinforcing plate 16 and the cable body portion 15, and the holding of the cable 17 by the cable holding tool 20 is released.

  After that, the locked state is confirmed (ST8). That is, in the connector lock tool 30, the actuator 32 is returned to the original position, the roller holding portion 34 and the roller 35 are retracted, and the robot portion 5 is operated to move the base portion 8 to the position shown in FIG. 12, that is, the distance measuring sensor 47. Is moved to a position where the height of the connector 13 can be measured. Then, as shown in FIG. 17 (c), the height of the height measurement position preset for confirmation of the locked state in the connector 13, for example, the height of the (A) position and the (C) position shown in FIG. When the difference between the heights at these two positions is less than or equal to a predetermined value measured by the sensor 47, it is determined that the cover member 14 is in the closed state in the connector 13 and the operation of the lock mechanism is good. Then, the cable mounting operation ends.

  On the other hand, in (ST8), when the height difference between the (A) position and the (C) position is greater than the predetermined value, the cover member 14 is not completely closed. It is determined that the lock mechanism is in an insufficient state, and the lock mechanism is not in a sufficiently functioning state. In this case, the notification unit 55 notifies the operator by displaying it on the operation panel 10 (ST9). As a result, it is confirmed that the connector 13 has a defect in the locked state after the cable is attached, and it is possible to prevent the defect in which the electronic device 4 in the incomplete locked state is sent to the next step.

  In the electronic device assembling method by the electronic device assembling apparatus 1 described above, first, the lock state confirming unit provided in the electronic apparatus assembling apparatus 1 confirms the state of the lock mechanism provided in the connector 13 to which the cable 17 is not attached. If the state of the lock mechanism is such that the cable 17 can be attached, the cable attaching mechanism configured to move the cable holding tool 20 by the robot unit 5 attaches the cable 17 to the connector 13.

  At the same time, the lock actuating mechanism configured to move the connector lock tool 30 by the robot unit 5 is actuated, and the lock mechanism provided in the connector 13 is actuated to lock the cable 17 with respect to the connector 13. Then, after that, the lock state confirmation unit confirms the state of the lock mechanism of the connector 13 to which the cable 17 is attached. That is, in the example shown here, the cable holding tool 20 and the connector lock tool 30 are configured to be moved by the single robot unit 5.

  In the above-described embodiment, as the cables 17 and 17A to be worked by the electronic device assembling apparatus 1, a reinforcing plate 16 for handling is provided at one end portion 15a of the cable body portion 15, and a mouth opening portion 17b (FIG. 5, FIG. 6) is provided in the embodiment, the work target of the electronic device assembling apparatus 1 is not limited to such a configuration example, and for example, modified examples shown in FIGS. It may be included in the work target.

  The cable 17B (first modified example) shown in FIG. 18 does not have the reinforcing plate 16 joined near the one end 15a of the cable body 15 and the cable body 15 itself is the work target as the cable 17B. That is, in the cable mounting operation, the cable main body portion 15 is held as it is, and the mounted portion 15b formed on the one end portion 15a of the cable main body portion 15 is mounted on the connector 13.

  A cable 17C (second modified example) shown in FIG. 19 has a reinforcing plate 16 joined thereto so as to cover the attached portion 15b set at one end 15a of the cable body 15 in the same manner as the cable 17A shown in FIG. In the configuration, the reinforcing plate 16 does not have the opening portion 17b separated from the cable body portion 15, and the entire surface of the reinforcing plate 16 is a joint portion 17a joined to the cable body portion 15. When the cable 17C is attached to the connector 13, not only the attached portion 15b but also the reinforcing plate 16 overlapping the attached portion 15b is attached to the connector 13 as in the example shown in FIG.

  The cables 17B and 17C having the above configuration cannot be held by the cable holding tool 20 shown in FIG. Therefore, when the cable mounting operation is performed on the cables 17B and 17C, for example, the cable holding tool 20A shown in FIG. 20 (first modification) and the cable holding tool 20B shown in FIG. 22 (second modification). ) Is used.

  The cable holding tool 20A of the first modified example shown in FIG. 20 holds the reinforcing plate 16 by being sandwiched by the chuck mechanism of the reinforcing plate 16 used in the cable holding tool 20 shown in FIG. 2, that is, the chuck block 27 and the blade 28. Instead of the configuration, a suction block 27A having a suction surface 27c for holding the cables 17B and 17C by vacuum suction is used. That is, like the cable holding tool 20, the suction block 27A is mounted on the front end surface (the surface on the advancing direction side) of the slide portion 26A that moves forward and backward by the actuator 25. The suction surface 27c provided on the suction block 27A is provided with a planar flat portion 27d and a curved curved portion 27e.

  The suction surface 27c is formed with a recess 27g in which the suction hole 27f is opened. With the cables 17B and 17C to be held in contact with the suction surface 27c, the cables 17B and 17C are suctioned to the suction surface 27c by vacuum suction from the suction holes 27f by a vacuum suction source (not shown). It can be held by the suction block 27A.

  The flat portion 27d has the same function as the protruding portion of the chuck surface 27a shown in FIG. 7B. That is, while the cables 17B and 17C are suction-held on the suction surface 27c, the cables 17B and 17C in a deformed state such as a warp shape or a wavy shape in the width direction are made to follow the flat portion 27d, thereby Deformation is corrected.

  FIG. 21 shows an operation when the cables 17B and 17C are attached to the connector 13 using the cable holding tool 20A of the first modified example. As shown in FIG. 21A, at the position corresponding to the connector 13 of the work target in the electronic device 4, the cables 17B and 17C in which the cable main body 15 is connected to the display device 12 (see FIG. 3) in advance are The mounted portion 15b is positioned with the posture facing upward. In the connector 13, the cover member 14 is in an open state, and the cables 17B and 17C can be attached. When the cable mounting operation is started, the cable holding tool 20A with the suction block 27A advanced is brought close to the back surface of the cables 17B and 17C with the suction block 27A being tilted (arrow p).

  Next, as shown in FIG. 21B, the cables 17B and 17C are pushed down and moved along the suction surface 27c (arrow q). At this time, the suction block 27A is aligned so that the mounted portions 15b of the cables 17B and 17C are in a state of protruding from the tip of the suction surface 27c, and in this state, vacuum suction is performed from the suction holes 27f (FIG. 20). Then, the cables 17B and 17C are suction-held by the suction block 27A.

  Then, in this state, the cable holding tool 20A is caused to perform a positioning operation (arrow r), so that the mounted portions 15b of the cables 17B and 17C sucked and held by the suction block 27A are positioned at the image pickup position by the image pickup unit 40. , The relative position of the mounted portion 15b and the connector 13 is detected. Then, the cable holding tool 20A is moved based on this relative position, and the mounted portion 15b is inserted into the mounting portion 13a of the connector 13 and mounted. Then, after that, the connector lock and the confirmation of the lock state are performed in the same manner as in the example shown in FIG.

  Next, the configuration of the cable holding tool 20B of the second modified example will be described with reference to FIG. The cable holding tool 20B has cables 17B and 17C instead of the chuck mechanism of the reinforcing plate 16 used in the cable holding tool 20 shown in FIG. 2, that is, the structure in which the reinforcing plate 16 is sandwiched and held by the chuck block 27 and the blade 28. The chuck head 29 is configured to directly sandwich and hold the vicinity of the mounted portion 15b in the vertical direction.

  Like the cable holding tool 20, the chuck head 29 is attached to the front end surface (the surface on the advancing direction side) of the slide portion 26B that moves forward and backward by the actuator 25. A pair of fixed chucks 29a and moving chucks 29b are vertically opposed to the side surface of the chuck head 29, that is, the surface on the side that contacts one side end surface of the mounted portion 15b when the chuck head 29 is advanced to the cables 17B and 17C. Are arranged. The lower fixed chuck 29a is fixedly arranged at the lower end of the suction surface 27c, and the upper movable chuck 29b is coupled to a movable member 29c that moves up and down along the chuck head 29. The moving member 29c moves up and down (arrow s) by a chuck driving mechanism (not shown) built in the chuck head 29.

  As shown in FIG. 22B, when the movable chuck 29b is raised with respect to the fixed chuck 29a, the cables 17B and 17C to be held are introduced between the fixed chuck 29a and the movable chuck 29b. A gap is formed. By driving the chuck drive mechanism with the cables 17B and 17C positioned in this gap, the movable chuck 29b descends (arrow t), and the cables 17B and 17C are interposed between the fixed chuck 29a and the movable chuck 29b. Sandwich and hold. At this time, the holding positions of the cables 17B and 17C are adjusted so that the attached portions 15b of the cables 17B and 17C are in a protruding state.

  FIG. 23 shows an operation when the cables 17B and 17C are attached to the connector 13 using the cable holding tool 20B of the second modified example. As shown in FIG. 23A, at the position corresponding to the connector 13 of the work target in the electronic device 4, the cables 17B and 17C in which the cable main body 15 is connected to the display device 12 (see FIG. 3) in advance are provided. The mounted portion 15b is positioned with the posture facing upward. In the connector 13, the cover member 14 is in an open state, and the cables 17B and 17C can be attached. In the chuck head 29 of the cable holding tool 20B, the movable chuck 29b is separated from the fixed chuck 29a and is in the chuck open state. When the cable mounting operation is started, the cable holding tool 20B in the state where the chuck head 29 is tilted and advanced is moved with respect to the cables 17B and 17C (arrow u), and the cables 17B and 17C are fixed chuck 29a and the moving chuck. It is located between 29b.

  Next, as shown in FIG. 23B, the chuck driving mechanism is driven in the chuck head 29 to bring the moving chuck 29b close to the fixed chuck 29a to bring the chuck into a closed state (arrow v). As a result, the cables 17B and 17C are sandwiched and held between the movable chuck 29b and the fixed chuck 29a. At this time, the chuck head 29 is aligned with the cables 17B and 17C so that the mounted portions 15b of the cables 17B and 17C are in a state of protruding from the chuck head 29.

  Then, in this state, the cable holding tool 20B is caused to perform a positioning operation (arrow w), so that the mounted portions 15b of the cables 17B and 17C held by the chuck head 29 are positioned at the image pickup position by the image pickup unit 40. The relative position of the mounted part 15b and the connector 13 is detected. Then, the cable holding tool 20B is moved based on this relative position, and the mounted portion 15b is inserted into the mounting portion 13a of the connector 13 and mounted. Then, after that, the connector lock and the confirmation of the lock state are performed in the same manner as in the example shown in FIG.

  As described above, in the present embodiment, the electronic device assembly apparatus 1 that mounts the mounted portion 15b of the cable 17 on the connector 13 of the electronic device 4 is a base on which the cable holding tool 20 and the connector lock tool 30 are mounted. The cable holding tool 20 and the connector lock tool 30 are moved relative to the electronic device 4 held on the work stage 3 by moving the unit 8 by the robot unit 5, and the cable 17 is attached to the connector 13. In the electronic device assembling method described above, the cable 17 is held by the cable holding tool 20, the cable holding tool 20 is moved to insert the mounted portion 15b of the cable 17 into the connector 13 of the electronic device 4, and the connector locking tool 30 is used to connect the connector. The lock mechanism provided in 13 is operated to connect the cable 17 to the connector 13. Tsu so that to click. As a result, the work of connecting the cable 17 to the connector 13 can be automated and the work efficiency can be improved by the equipment having a simple structure.

  Further, in the present embodiment, in the electronic device assembling apparatus 1 described above, a cable mounting mechanism that holds the cable 17 and mounts the cable 17 on the cable 17 by the configuration in which the cable holding tool 20 is moved by the robot unit, and the connector lock tool 30 are installed in the robot. A lock operation mechanism that operates a lock mechanism provided in the connector 13 by moving the connector 5; and a lock state confirmation unit that confirms the state of the lock mechanism by measuring the height of the connector 13 by the distance measurement sensor 47, And a control unit for controlling the cable mounting mechanism and the lock actuating mechanism.

  Then, in the electronic device assembling method in which the cable 17 is attached to the connector 13 by the electronic device assembling apparatus 1, the lock state confirming unit confirms the state of the lock mechanism provided in the connector 13 to which the cable 17 is not attached, and If the state is such that the cable 17 can be attached, the cable attaching mechanism attaches the cable 17 to the connector 13, activates the lock operating mechanism to activate the lock mechanism, and the lock state confirming unit attaches the cable 17. The state of the lock mechanism of the connector 13 is confirmed. As a result, when the cable 17 is attached to the connector 13 with the lock mechanism, the electronic device 4 in the incompletely connected state is prevented from being sent to the subsequent process, and the reliability of the connected state after the attachment is improved. Can be secured.

  INDUSTRIAL APPLICABILITY The electronic device assembling apparatus and the electronic device assembling method according to the present invention have an effect that, when a cable is attached to a connector having a lock mechanism, the reliability of the connection state after attachment can be ensured, and the cable is electronic It is useful in the field of electronic equipment assembly to be attached to the connector of equipment.

DESCRIPTION OF SYMBOLS 1 Electronic device assembly device 3 Work stage 4 Electronic device 5 Robot part 8 Base part 13 Connector 14 Cover member 15 Cable main body part 15b Attached part 16 Reinforcing plate 17, 17A, 17B, 17C Cable 17b Opening part 20 Cable holding tool 27 Chuck block 27c Adsorption surface 28 Blade 30 Connector lock tool 33 Buffer unit 35 Roller 40 Imaging unit 43 Camera 46 Illumination 47 Distance measuring sensor

Claims (12)

A cable mounting mechanism that holds a cable and mounts a mounted portion of the cable on a connector of an electronic device,
A lock actuation mechanism for actuating a lock mechanism provided in the connector;
A lock state confirmation section for confirming the state of the lock mechanism of the connector,
A control unit for controlling the cable mounting mechanism and the lock operating mechanism,
The control unit is
When the lock state confirmation unit determines that the cable is open, the cable attachment mechanism attaches the cable to the connector,
Further comprising a base portion having the cable mounting mechanism and the lock operating mechanism,
The cable attachment mechanism includes a cable retention tool for retaining the cable,
The lock actuation mechanism includes a connector lock tool for actuating the lock mechanism;
An electronic device assembling apparatus, wherein the cable holding tool and the connector lock tool are mounted on the base portion so as to face each other. The control unit is
The electronic device assembling apparatus according to claim 1, wherein the base attachment is moved above the connector, and the cable is attached to the connector by the cable attaching mechanism when the lock state confirming unit determines the open state. . A lock state in which the lock state confirmation unit determines the state of the lock mechanism based on the measurement result of the distance measurement sensor and the distance measurement sensor that measures the height of a portion where the height changes depending on the state of the lock mechanism. It has a judgment part,
The electronic device assembling apparatus according to claim 1, wherein the cable holding tool and the connector lock tool are opposed to each other with a measurement optical axis of the distance measurement sensor provided in the base portion interposed therebetween. The lock state confirmation unit includes an image capturing unit capable of capturing an image of the connector, and a lock state determining unit configured to determine a state of the lock mechanism based on an image captured by the image capturing unit,
The electronic device assembling apparatus according to claim 1, wherein the cable holding tool and the connector lock tool are opposed to each other with an imaging optical axis of the imaging unit provided in the base section interposed therebetween. The lock state confirmation unit confirms the state of the lock mechanism of the connector before the cable is attached,
As a result of the confirmation, when it is determined that the lock mechanism is functioning or the work of attaching the cable is hindered, the control unit stops the work of attaching the cable to the connector and the operator. The electronic device assembling apparatus according to any one of claims 1 to 4, wherein the electronic device assembling apparatus notifies the fact to the user. The lock state confirmation unit confirms the state of the lock mechanism of the connector to which the cable is attached,
The electronic device according to claim 1, wherein, when it is determined that the lock mechanism is not sufficiently functioning as a result of the confirmation, the control unit notifies the operator to that effect. Assembly equipment. Using the electronic device assembling apparatus according to any one of claims 1 to 6,
A method of assembling an electronic device, wherein an attached part of a cable is attached to a connector of an electronic device,
The lock state confirmation section confirms the state of the lock mechanism provided in the connector where the cable is not attached,
When it is determined by the lock state confirmation unit that the cable is in the open state, the cable attachment mechanism attaches the cable to the connector, activates the lock actuation mechanism to activate the lock mechanism,
An electronic device assembling method , wherein the lock state confirmation unit confirms a state of the lock mechanism of a connector to which the cable is attached.   The electronic device assembling method according to claim 7, wherein the confirmation of the state of the lock mechanism by the lock state confirmation unit is performed by moving the base unit above the connector.   9. The electronic device assembly method according to claim 7, wherein the confirmation of the state of the lock mechanism by the lock state confirmation unit is performed by measuring the height of a portion where the height changes depending on the state of the lock mechanism.   9. The electronic device assembling method according to claim 7, wherein the confirmation of the state of the lock mechanism by the lock state confirmation unit determines the state of the lock mechanism based on an image of the connector.   When it is determined that the state of the lock mechanism of the connector to which the cable is not attached is the state in which the lock mechanism is functioning or the operation of attaching the cable is hindered, the cable attachment mechanism is 11. The electronic device assembling method according to claim 7, wherein the work of attaching the cable to the connector is stopped, and the notification unit notifies the operator of that fact.   8. The notification unit notifies the operator to that effect when it is determined that the state of the lock mechanism of the connector to which the cable is attached is not in a state in which the lock mechanism is fully functioning. 11. The electronic device assembling method according to any one of 11.

Images