JP2008192824A - Component mounting machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a component mounting machine which can correct the position of a board on the board conveyance path automatically when the operation is resumed after recovering from a failure due to a cause relevant to conveyance of the board. <P>SOLUTION: The component mounting machine comprises a controller 70 for controlling the driving of a board conveyer. The controller 70 comprises a means 82 for detecting the position of a board on the board conveyance path based on the signals from board sensors 56a and 56b when the operation is resumed after recovering from a failure due to a cause relevant to conveyance of the board, and a control means 83 for moving the board to a regular position by driving the board conveyer if the position of the board detected by the board position detection means 82 is shifted from the regular position. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a component mounter that includes a plurality of mounting stages and is capable of sequentially transporting a substrate to be mounted across each mounting stage.

  2. Description of the Related Art Conventionally, a component mounting machine having a mounting stage for mounting a required number of electronic components on a substrate to be mounted by a mounting head and a transfer device for carrying the substrate in and out of the mounting stage is generally used. Are known.

In particular, in order to increase mounting efficiency, as shown in Patent Document 1 below, a plurality of mounting stages are provided so that electronic components can be mounted simultaneously on a plurality of substrates, and each mounting is performed from the substrate carry-in portion. There is also known a mounting machine in which a transport device that sequentially transports a substrate over a stage and a substrate unloading unit is provided so that a plurality of substrates that have been mounted on each mounting stage can be simultaneously transported downstream.
JP 2002-208797 A

  In this type of mounting machine, the substrate may be stopped in the middle of conveyance because the substrate may be caught in the middle or a malfunction of the conveyance device may occur during the conveyance of the substrate by the conveyance device. When a failure due to a cause related to board transportation occurs, after the operation of the mounting machine is stopped, work to eliminate the cause of the failure is performed, and the board stopped during transportation is moved to a normal position. The operation is resumed after the position correction work to be performed is performed.

  In this case, the position correction work has conventionally been performed manually by an operator. However, in a mounting machine equipped with a large number of mounting stages, a large number of substrates on the substrate transport path are transported, so if a failure occurs during the transport, the position of each substrate can be confirmed and each substrate can be The movement to the position becomes very complicated.

  The present invention has been made in view of such circumstances, and in a component mounter including a plurality of mounting stages and a substrate transport apparatus that transports a substrate across each stage, a failure occurs due to a cause related to substrate transport. Providing a component mounter that can automatically perform the work of moving the board on the board transport path to the proper position when it is later restored and restarted. Objective.

  In order to solve the above-described problems, a component mounting machine according to the present invention includes a plurality of mounting stages that perform mounting of electronic components on a substrate to be mounted side by side in the substrate transport direction, and substrate transport that passes through each of the mounting stages. The substrate is provided on the path, and the substrate is sequentially transferred from the substrate carry-in portion on the upstream side of the substrate transfer route to the substrate carry-out portion on the downstream side of the substrate transfer route through each mounting stage, and simultaneously transfers a plurality of substrates on the substrate transfer route. A substrate transfer device, a substrate detection sensor that is provided in the substrate transfer device and detects a substrate on a substrate transfer path, and a control device that controls the drive of the substrate transfer device. Substrate position detection means for detecting the position of the substrate on the substrate transfer path based on a signal from the substrate detection sensor when restarting operation after the occurrence of a failure due to a cause related to transfer; and the substrate position detection Substrate position detected by stage in which a control means for the substrate position correction control to move the substrate by driving the substrate transfer apparatus to the normal position when displaced from the normal position.

  According to this component mounting machine, when the operation is resumed, the board position is detected by the board position detection means based on the signal from the board detection sensor, and the board by the board position correction control means in accordance with the detection of the board position. The position of the substrate on the substrate transport path is automatically corrected by the control of the transport device.

  In this component mounting machine, the board transfer device extends in the direction of the board transfer path over the mounting stages, and is capable of moving in this direction, a transfer axis driving means for driving the transfer axis, and the transfer axis. Provided for each mounting stage, and a plurality of pushing members for pushing the substrate on the substrate carrying path of each mounting stage, and the pushing member can push the substrate as the carrying shaft moves. It is preferable that a pressing member driving means for changing the position between the substrate pressing position and the retracted position away from the substrate is provided, and a substrate detection sensor is provided on the transport shaft.

  If it does in this way, at the time of substrate conveyance, a substrate will be conveyed by moving a conveyance axis in the state where the above-mentioned pushing member was made into a substrate pushing position. Further, when the substrate position is detected by the substrate position detecting means, the substrate is searched by reading a signal from the substrate detection sensor while moving the transport shaft in a state in which each pushing member is in the retracted position. The position can be detected.

  In such a structure, the transport axis can be reciprocated in the direction of the substrate transport path within a movable range corresponding to one stage of the mounting stage, and the substrate detection sensor corresponds to the length between the mounting stages. Preferably, each mounting stage is provided at a pitch.

  In this way, the substrate can be searched over the required range including each mounting stage and each stage on the substrate conveyance path by simply moving the conveyance axis by one stage, and the substrate position can be detected quickly. it can.

  Further, it is preferable that a pair of the substrate detection sensors is provided for each mounting stage, and the distance between the pair of substrate detection sensors is adjusted to be substantially the same as the length of the substrate.

  In this way, the substrate position is accurately detected.

  Further, a pair of the pushing members are provided for each mounting stage, and the pair of pushing members can transport the substrate on the substrate transport path in a state of being sandwiched from both the upstream side and the downstream side. It is preferable that the distance between the pressing members is adjusted.

  In this way, the substrate can be transported stably.

  Further, the substrate position correction control means transfers the substrate in a state where all of the pair of pressing members provided for each mounting stage are set to the substrate pressing position as control for moving the substrate to a normal position. The first position correction control mode for collectively moving the substrates on the path and the substrates on the substrate transport path in a state where only the upstream side pressing member is set to the substrate pressing position for all pairs of the pressing members. And a second position correction control mode in which the substrates on the substrate transport path are individually moved in a state where only the pressing members corresponding to some mounting stages are set to the substrate pressing position. It is preferable that the control mode is selectively executed according to the state of the positional deviation of the substrate on the substrate transport path.

  In this way, it is possible to quickly correct the position by moving a plurality of substrates at once as much as possible.

  As described above, according to the component mounter of the present invention, the position of the board on the board transport path can be automatically corrected when the operation is resumed after the occurrence of a failure due to a board transport related cause. There is no need to manually correct the substrate position, and there is no need to perform complicated position correction work even when a large number of substrates are present in the substrate transport path. Therefore, the work for resuming the operation becomes very simple.

  A preferred embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a plan view showing a schematic configuration of a component mounting machine (hereinafter referred to simply as a mounting machine) according to an embodiment of the present invention, FIG. 2 is a plan view showing a detailed structure of the mounting machine, and FIG. FIG.

  In these drawings, the mounting machine 1 sends the printed circuit board (substrate to be mounted) 3 from the upstream end (one end) toward the downstream end (the other end), and is arranged in this transport direction. Further, electronic components (not shown) are respectively mounted on the printed circuit board 3 by the first to fourth mounting stages 4 to 7. In the following, the direction parallel to the transport direction is referred to as the X direction, and the direction orthogonal thereto is simply referred to as the Y direction.

  The mounting machine 1 receives a printed circuit board 3 from a base 11 for supporting each device to be described later, the four mounting stages 4 to 7 described above, and an upstream device (not shown) adjacent to the upstream end. The printed circuit board 3 is received from a carry-in stage (substrate carry-in section) 8 provided with a carry-in device 12 for sending it to the first mounting stage 4 located on the most upstream side, and a fourth mounting stage 7 located on the most downstream side. , A carry-out stage (substrate carry-out unit) 9 provided with a carry-out device 13 for carrying out to a downstream device that performs a post-process not shown in the figure, and a substrate for moving the printed board 3 in the X direction between these stages And a transport device 51.

  On the base 11, first to sixth Y frames 16 to 21 are provided. As shown in FIGS. 1 and 2, these first to sixth Y frames 16 to 21 are provided to extend in the Y direction at six locations on the base 11 at predetermined intervals in the X direction. . Among these Y frames 16 to 21, the first, third, and fifth Y frames 16, 18, and 20 located first, third, and fifth from the upstream side in the transport direction are One end portion in the Y direction (hereinafter, this end portion is referred to as the device front side) extends from the other end side (device rear side), and the other second, fourth, and sixth Y frames 17, 19, and 21 It is formed so as to extend from the end portion in the Y direction which is the side to the front side of the apparatus. The front end portions of the Y frames 18 and 20 and the rear end portions of the Y frames 17 and 19 reach the vicinity of an arrangement position of the post-feed shaft 52 in the central portion in the apparatus Y direction. Further, as shown in FIG. 3, a recess 22 for passing the printed circuit board 3 is formed in a portion corresponding to the center portion in the Y direction of the base 11 in the first to sixth Y frames 16 to 21. ing.

  The four mounting stages 4 to 7 are formed to have the same structure except that the mounting position on the base 11 and the arrangement direction of the members are different. Therefore, here, the first mounting stage 4 positioned on the most upstream side will be described, and the other mounting stages 5 to 7 will be assigned the same reference numerals and detailed description thereof will be omitted.

  2 and 3, the mounting stage 4 includes a transfer means 23 for moving the printed circuit board 3 in the Y direction between a transfer position and a mounting position, which will be described later, and one side of the transfer means 23 in the Y direction. The electronic component supply device 25 including a large number of tape feeders 24, 24... Provided adjacent to the device front side, and the electronic component transfer for transferring the electronic components from the tape feeder 24 to the printed circuit board 3. Loading device 26.

  As shown in FIG. 3, the transfer means 23 includes a pair of guide rails 31, 31 provided on the base 11 so as to extend in the Y direction, and a table 32 movably supported by these guide rails 31. And a Y-direction drive device 33 for moving the table 32 in the Y direction, a conveyor 34 provided on the table 32, and a clamp mechanism 35 for restricting the movement of the printed circuit board 3 with respect to the table 32. It is configured.

  The Y-direction drive device 33 includes a ball screw shaft 33a that is rotatably supported on the base 11 in a state extending in the Y direction, a motor 33b that rotates the ball screw shaft 33a, and a screw screwed to the ball screw shaft 33a. And a ball nut 33c fixed to the table 32 and the like. The Y-direction drive device 33 is configured to reciprocate the table 32 between a transport position indicated by a solid line in FIG. 1 and a mounting position indicated by a two-dot chain line in FIG. . The transport position is positioned at the center of the base 11 in the Y direction, and the mounting position is positioned near the tape feeder 24.

  The conveyor 34 is constituted by a pair of endless belts 34a and supports both ends of the printed circuit board 3 in the Y direction. The printed circuit board 3 is pressed in the X direction (transport direction) by driving a substrate transport device 51 described later. Is rotated by.

  As shown in FIG. 3, the clamp mechanism 35 includes a pair of pressure receiving members 35a and 35a located above both ends in the Y direction of the printed circuit board 3, and pushes the printed circuit board 3 from below to press the pressure receiving member 35a. And a push-up device 35b for supporting the table 32.

  As shown in FIGS. 2 and 3, the electronic component transfer device 26 of the first mounting stage 4 is provided at the upper ends of the first and third Y frames 16 and 18 so as to extend in the Y direction. A pair of first guide rails 41, 41, and a support member that is horizontally mounted between the first guide rails 41, 41, extends in the X direction, and is movably supported by the first guide rail 41. 42, a pair of Y-direction drive devices 43 and 43 for driving the support member 42, a second guide rail 44 provided on the support member 42 and extending in the X direction, and moved to the second guide rail 44 A head unit 45 that is freely supported, an X-direction drive device 46 that drives the head unit 45, and a lift device (see FIG. 3) that includes a Z-axis motor 47 and the like are supported by the head unit 45 so as to be movable up and down. Is It is composed of a plurality of suction heads 48 and the like. As shown in FIG. 3, the suction head 48 is composed of a suction nozzle 48a for sucking electronic components, a rotation drive device including an R-axis motor 48b for rotating the suction nozzle 48a about an axis in the vertical direction, and the like. It has.

  The Y-direction drive device 43 includes a motor 43a fixed to one end portion (end portion on the front side of the device) of the first and third Y frames 16 and 18, and one end portion connected to the motor 43a in the Y direction. A ball screw shaft 43b that extends and is rotatably supported by the Y frames 16 and 18, and a ball nut 43c (see FIG. 3) that is rotatably supported by the support member 42 and screwed to the ball screw shaft 43b. It is constituted by.

  The X-direction drive device 46 includes a motor 46a fixed to one end portion in the X direction of the support member 42, one end portion connected to the motor 46a, extending in the X direction, and rotatably supported by the support member 42. The ball screw shaft 46b and a ball nut (not shown) that is rotatably supported by the head unit 45 and screwed to the ball screw shaft 46b.

  The electronic component transfer apparatus 26 according to this embodiment moves the suction head 48 in the X direction and the Y direction to transfer the electronic component from the tape feeder 24 to the printed circuit board 3 at the mounting position.

  Further, although not shown in FIGS. 1 to 3, the head unit 45 of the electronic component transfer device 26 is an image pickup device (FIG. 6) for detecting the position of the printed circuit board 3 positioned at the mounting position. A substrate camera 79) shown in FIG. 6 and an imaging device (component camera 80 shown in FIG. 6) for detecting the position of the electronic component sucked by the suction nozzle 48a are provided. This imaging device can also be provided on the base 11.

  As shown in FIGS. 1 and 2, the mounting stages 4 to 7 configured in this manner are mounted on the base 11 in a staggered pattern from the upstream side to the downstream side in the transport direction in plan view. ing. As shown in FIG. 1, in the state where the table 32 (printed circuit board 3) of each transfer means 23 is moved to the transport position, the conveyors 34 on these tables 32 are positioned at the same position in the Y direction. (Arranged in a row in the X direction) on the base 11.

  The table 32 of each of the mounting stages 4 to 7 is provided at a position close to each other in a state where the table 32 is positioned at the transfer position. The printed circuit board 3 placed on the conveyor 34 on the table 32 moves directly from the upstream conveyor 34 to the downstream conveyor 34 by being pushed from the upstream side in the transport direction. The driving of the printed circuit board 3 is performed by a substrate transfer device 51 described later.

  In the mounting machine 1 according to this embodiment, as shown in FIG. 1, the center of the base 11 in the Y direction is moved by the conveyor 34 on the table 32 of each of the mounting stages 4 to 7 moved to the transfer position as described above. A substrate transport path 50 extending in the X-axis direction is formed in the section.

  As shown in FIGS. 2 and 3 and schematically shown in FIG. 4, the substrate transport device 51 includes a transport shaft 52 disposed above the substrate transport path 50, and the transport shaft 52 in the X-axis direction. A transfer shaft drive mechanism that moves the drive shaft, push members 53a and 53b for each mounting stage extending downward from the transfer shaft 52, a push member drive mechanism that drives the push members 53a and 53b, a substrate detection sensor 56a, 56b.

  The transport shaft 52 extends in the X-axis direction across the mounting stages 4 to 7. The transport shaft driving mechanism is composed of a motor 54, a transmission mechanism, and the like, and can reciprocate the transport shaft 52 in the X-axis direction downstream and upstream by a predetermined stroke corresponding to one stage of the mounting stage. It can be done.

  A pair of the pressing members 53a and 53b is arranged for each mounting stage at a pitch corresponding to the length between the stages. Each of the pushing members 53a and 53b is changed in position between a board pushing position where the board can be pushed along with the movement of the transport shaft and a retreat position away from the board. More specifically, each of the pushing members 53a and 53b can be moved up and down between a board pushing position that protrudes downward from the transport shaft 52 and is adjacent to the printed board 3 and a retreat position that rises from the printed board 3. Alternatively, it is possible to undulate between a standing state corresponding to the substrate pushing position and a lying state corresponding to the retracted position.

  The pushing member driving mechanism includes a motor 55 and the like, and is provided for each of the pushing members 53a and 53b. The pushing member 53a and 53b is repositioned with respect to the substrate pushing position retracted position ( Elevate or undulate).

  At the time of transport, the pushing members 53a and 53b are set to the retracted position (in a lying state), and the transport shaft 52 is located on the upstream side of the movable range (see FIG. 4A). When the upper printed circuit board 3 is transported, the transporting shaft 52 moves (forward) in a state where the pressing members 53a and 53b are at the substrate pressing position, whereby the pressing members 53a and 53b are moved to the substrate. The printed circuit board 3 on the conveyance path 50 is pushed downstream (see FIGS. 4B and 4C). After conveyance, the pushing members 53a and 53b are moved to the retracted position and the conveyance shaft 52 is moved upstream. By moving (returning), it is returned to the initial position (FIG. 4A).

  In addition, the position of one of the pair of pressing members 53a and 53b can be changed in the substrate transport direction, so that the interval between the pressing members 53a and 53b is variable. The distance between the pushing members 53a and 53b is adjusted so as to correspond to the length. When the pair of pushing members 53a and 53b are set to the board pushing position, the printed board 3 on the board carrying path 50 can be carried while being sandwiched from both the upstream side and the downstream side. That is, the printed board 3 can be conveyed while the printed board 3 is held by the downstream pushing member 53b so as not to be displaced while being pushed by the upstream pushing member 53a of the pair. It can be done.

  Further, in this embodiment, five pairs of push members 53a and 53b are provided, and when the transport shaft 52 is located on the upstream side of the movable range, the five pairs of push members 53a and 53b are mounted on the carry-in stage 8 and each mounting. Corresponding to the stages 4 to 7, when the transport shaft 52 moves to the downstream side of the movable range, the five pairs of pushing members 53a and 53b are arranged so as to correspond to the mounting stages 4 to 7 and the unloading stage 9, respectively. ing.

  In this way, the printed circuit board 3 is sequentially conveyed from the carry-in stage 8 through the mounting stages 4 to 7 to the carry-out stage 9 one by one by the operation of the board conveying device 51, and the printed board 3 on the board conveyance path is 1 The substrate transfer device 51 is configured so that one or more can be transferred simultaneously. That is, when only one printed circuit board 3 on the substrate transport path is to be transported downstream, the transport shaft 52 is moved downstream with the pair of pushing members 53 corresponding to the substrate in the substrate pushing position. In the state where the plurality of printed circuit boards 3 moved to the transfer positions on the plurality of stages are located on the substrate transfer path and are to be moved downstream, The plurality of printed circuit boards 3 can be simultaneously transported by moving the transport shaft 52 to the downstream side in a state where the plurality of pairs of pressing members 53 corresponding to the respective printed circuit boards 3 are set to the substrate push position. In this embodiment, a maximum of five printed circuit boards 3 can be simultaneously conveyed.

  The endless belt 34a of the conveyor 34 described above is rotatable, and the endless belt 62a of the conveyor 62 of the loading and unloading devices 12 and 13 described below is also not driven (except when driving for loading or unloading substrates). ) Is freely rotatable, the endless belt in contact with the printed circuit board 3 to be conveyed is rotated with the movement of the printed circuit board 3 when the substrate is conveyed by the substrate conveying device 51.

  The substrate detection sensors 56a and 56b detect the printed circuit board 3 when positioned above the printed circuit board 3, and are configured by, for example, a reflective optical sensor. Similarly to the push members 53a and 56b, a pair of substrate detection sensors 56a and 56b are provided for each mounting stage, and five pairs are provided in this embodiment.

  As shown in FIG. 5, sensor pairs (a pair of substrate detection sensors 56a and 56b) are arranged at the same pitch as the interstage length L1. Further, the substrate detection sensors 56a and 56b are arranged in the vicinity of the pushing members 53a and 53b, and the interval between the substrate detection sensors 56a and 56b is made variable in conjunction with the pushing members 53a and 53b, and is transported. The space | interval of the board | substrate detection sensors 56a and 56b is adjusted so that it may become substantially equal to the length L2 of the printed circuit board 3 (it becomes slightly small).

  The driving of the substrate transport device 51 is controlled by a controller 70 (see FIG. 6) described later as a control device.

  Further, as shown in FIG. 2, the carry-in device 12 provided in the carry-in stage 8 and the carry-out device 13 provided in the carry-out stage 9 include a table 61 provided on the base 11 so as to be movable in the Y direction, A conveyor 62 mounted on the table 61 and a Y-direction drive device 63 that moves the table 61 in the Y direction are configured. The Y-direction drive device 63 of these loading / unloading devices 12 and 13 includes a loading position located on the substrate conveyance path 50 and a loading / unloading position spaced from the substrate conveyance path 50 to the front side of the apparatus (downward in FIG. 2). The structure which moves the table 61 between unloading positions is taken.

  The conveyors 62 of the carry-in and carry-out devices 12 and 13 are endless belts 62a and 62a that support both ends of the printed circuit board 3 in the Y direction, and a drive device (not shown) for rotating these endless belts 62a and 62a. And. The endless belts 62a and 62a of the conveyor 62 of the carry-in device 12 are connected to the drive device when the substrate is loaded from the upstream device, and the carry-out device 13 is loaded when the substrate is unloaded to the downstream device. The endless belts 62a and 62a of the conveyor 62 are connected to the driving device. In these cases, the driving of the conveyor 62 is performed by the driving device. In other cases, the endless belts 62a and 62a are separated from the driving device and can be rotated. It has come to be.

  Further, the conveyor 62 includes a width adjusting mechanism (not shown) so that the position in the Y direction of the endless belt 62a located on one end side in the Y direction can be changed according to the width of the printed circuit board 3. Yes.

  The conveyor 62 is first, so that the printed circuit board 3 can move directly between the conveyors 34 of the first or fourth mounting stages 4 and 7 adjacent to each other in a state where the conveyor 62 is located at the transfer position. The fourth mounting stages 4 and 7 are disposed at positions close to the conveyor 34 in the X direction.

  As shown in FIG. 1, the carry-in device 12 is configured to be connected to an upstream device that performs a pre-process while the conveyor 62 is moved to the carry-in position. It is comprised so that it may be connected to the downstream apparatus which performs a post process in the state which has moved to the carrying-out position.

  FIG. 6 shows a configuration of a controller (control device) 70 provided in the mounting machine 1.

  In this figure, a controller 70 includes an arithmetic processing unit 71 constituted by a CPU, a mounting program storage unit 72 that stores a mounting program, and a transfer system data storage unit 73 that stores various data for board transfer and the like. , X-axis, Y-axis, Z-axis, and R-axis motors 46 a, 43 a, 47, 48 b for driving the head unit 45 and the suction head 48, and the motor 54 and the pushing member of the transport shaft driving mechanism in the substrate transport device 51. A motor control unit 74 that controls the motor 55 of the drive mechanism, an external input / output unit 75, and an image processing unit 76 are provided.

  The motor control unit 74 controls each motor based on a command from the arithmetic processing unit 71. Various sensors 77 are connected to the external input / output unit 75 as input elements, and various drive units 78 are connected as output elements.

  A substrate camera 79 and a component camera 80 are connected to the image processing unit 76, and image signals from these cameras are taken into the image processing unit 76 and subjected to predetermined image processing. Data is sent to the arithmetic processing unit 71.

  The arithmetic processing unit 71 controls the motors 54 and 55 of the substrate transport device 51 during substrate transport, and controls the motors 46a, 43a, 47, and 48b for operating the head unit 45 and the suction head 48 during mounting work. In addition to the control through the motor control unit 74, the control of various drive units and the like is performed through the external input / output unit 75, and a signal is transmitted to the external display unit 81.

  Further, the arithmetic processing unit 71 has functions of a substrate position detection unit 82 and a substrate position correction control unit 83 for control at the time of restarting operation after a failure due to a cause related to substrate conveyance.

  The substrate position detecting means 82 checks the change in the signal from the substrate detection sensor while moving the substrate detection sensors 56a and 56b together with the transfer shaft 52 when the operation is restarted after the occurrence of a failure due to the cause related to the substrate transfer. Detect the substrate position.

  That is, as shown in FIG. 7, when the transport shaft 52 moves from the upstream side with respect to the printed circuit board 3 on the substrate transport path 50, only one sensor (downstream sensor) 56b of the sensor pair is first turned on. Next, when the sensor 56b moves to the downstream end of the printed circuit board 3, both the sensors 56a and 56b are turned on. When the transport shaft 52 is further moved, only the other sensor 56a is turned on.

  Therefore, the position where both sensors 56a and 56b are turned on is detected as the position of the printed circuit board.

  Further, the substrate position correcting control means 83 is configured to provide a transport shaft driving mechanism (motor 54) and a pushing member of the substrate transport apparatus 51 when the substrate position detected by the substrate position detecting means 82 is deviated from the normal position. A drive mechanism (motor 55) is driven to control the printed circuit board to move to a normal position.

  In the present embodiment, as the control for moving the printed circuit board 3 to the regular position, as will be described in detail later, all the five pairs of pushing members 53a and 53b are set on the board conveyance path 50 in a state where the board pushing positions are set. The first position correction control mode for moving the plurality of printed circuit boards 3 at a time, and the plurality of five pairs on the substrate transport path 50 in the state where only the upstream side pressing members 53a are set to the substrate pressing positions. A printed circuit board on the substrate conveyance path 50 in the second position correction control mode for moving the printed circuit board 3 at a time and only the pressing members 53a and 53b corresponding to some mounting stages are set to the substrate pressing position. The third position correction control mode for individually moving the position of the printed circuit board 3 is selectively executed according to the state of positional deviation of the printed circuit board 3 on the circuit board conveyance path 50.

  A specific example of the processing of the arithmetic processing unit 71 as the substrate position detecting means 82 and the substrate position correcting control means 83 will be described with reference to the flowcharts of FIGS.

  FIG. 8 shows the overall flow. In this flowchart, first, the conveyance of the printed circuit board 3 is started (step S1), and then it is determined whether or not an error (failure) related to the substrate conveyance has occurred (step S2).

  If no error has occurred, the conveyance is continued, and the conveyance is completed by conveying the printed circuit board 3 to the downstream stage (step S3). Next, the mounting is started and the required number of electronic components are mounted. If it is done, the implementation is completed and the process returns. Then, the conveyance of the printed circuit board 3 to the downstream side and the mounting on the mounting stages 4 to 7 are repeated.

  When it is determined in step S2 that an error has occurred, the operation of the machine (mounting machine) is stopped (step S6). Then, after the operator performs recovery work such as removing the cause of the error, the operation of the machine is resumed (step S7).

  When the operation is resumed, a substrate search and movement process (step S8), which will be described later, is performed. After completion of this process (step S9), the process proceeds to step S4 and mounting is started.

  FIG. 9 shows a routine of the substrate search / transfer process on the transport path performed in step S8. This process is automatically executed when the operation is resumed, or is automatically executed by pressing the “board search button” on the operation screen of the display unit 81 after the machine operation is stopped due to an error. .

  When this process is started, a transport axis search (movement of the transport axis 52 for substrate search) is started (step S11), and the sensor pair (56a, 56b) is moved while moving the transport axis 52 as shown in FIG. Substrate search is performed by examining changes in the signal. When the five pairs of board detection sensors 56a and 56b are called the first to fifth sensor pairs in order from the upstream side, it is determined whether or not the sensor pair has found the printed board 3 for each of the first to fifth sensor pairs. (Steps S12 to S16). In the present embodiment, the printed circuit board 3 is found when both the sensors 56a and 56b of the sensor pair are simultaneously turned on.

  When the printed circuit board 3 is discovered for each of the sensor pairs, the discovery position (position of the transport shaft 52 at the time of discovery) is stored (steps S17 to S21).

  After the substrate position is detected in this way (processing as the substrate position detecting means 82), the substrate pitch and the substrate interval for each discovered printed circuit board 3 are calculated based on the substrate discovery position by each sensor pair. (Step S22).

  Next, control by the substrate position correction control means 83 is performed. This control will be described with reference to the operation explanatory diagrams of FIGS.

  As the control by the substrate position correcting control means 83, the state of positional deviation of the printed circuit board 3 on the substrate conveyance path 50 (especially the positional relationship of each substrate) is examined based on the calculation in step S22. It is determined whether or not the position of the transport shaft 52 when the sensor pair substrate is found is the same position (step S23).

  If this determination is YES, it means that the printed circuit boards 3 are arranged at the same pitch as the sensor pairs. In this case, steps S24 to S26 are executed as the first position correction control mode, and the conveying shaft 52 and the pushing members 53a and 53b are controlled as shown in FIG.

  That is, the transport shaft 52 moves to the substrate finding position (step S24), and then all the pushing members 53a and 53b are lowered to the substrate pushing position as shown in FIG. 10A (step S25). Then, as shown in FIG. 10B, the transport shaft 52 moves to the transport target position (regular substrate position) (step S26). By controlling the substrate transport device 51 so that these operations are performed, a plurality of discovered printed circuit boards 3 are transported collectively.

  If the determination in step S23 is NO, it is determined whether or not the variation in the substrate pitch is equal to or less than a predetermined value and each substrate interval has a margin for lowering the upstream pushing member 53a (step S27).

  If this determination is YES, steps S26 to S28 are executed as the second position correction control mode, and the conveying shaft 52 and the pushing members 53a and 53b are controlled as shown in FIG.

  That is, the transport shaft 52 moves to a position where the upstream side pushing member 53a of the pushing member pair can be lowered with respect to the found board (step S28), and then the board found as shown in FIG. All of the upstream side pushing members 53a of the position are lowered to the board pushing position (step S29). Then, as shown in FIG. 11B, the transport shaft 52 moves to the transport target position (step S30). By controlling the substrate transport device 51 so that these operations are performed, a plurality of discovered printed circuit boards 3 are transported collectively.

  When the determination in step S27 is NO, steps S31 to S34 are executed as the third position correction control mode, and the conveyance shaft 52 and the pushing members 53a and 53b are controlled as shown in FIG.

  That is, first, the conveyance shaft 52 is controlled to move to the board finding position of the most downstream sensor pair, and then, as shown in FIG. 12A, the pushing members 53a, 53a, corresponding to the board finding position of the target sensor pair. 53b is lowered to the substrate pushing position (step S32), and then the transport shaft 52 is moved to the transport target position as shown in FIG. 12B (step S33). Further, it is determined whether or not all the discovered substrates have been transferred (step S34). If not completed, the process returns to step S31 and the following processing is performed again, so that FIGS. As described above, the processes in steps S32 to S34 are performed on the second printed circuit board from the most downstream side. Then, the substrate transfer device 51 is controlled so that these operations are repeated until the transfer of all the discovered substrates is completed, whereby the printed circuit boards 3 on the substrate transfer path 50 are individually moved to the target position sequentially from the downstream side. Be transported.

  According to the mounting machine of the present embodiment as described above, the printed circuit board 3 is caught in the middle of the substrate transportation for some reason or malfunction of the substrate transportation device 51 occurs, and the printed circuit board 3 stops in the middle of the transportation. After the occurrence of such a failure, when the operation is resumed after the restoration work for removing the cause of the failure is performed, the substrate position detection unit 82 detects the substrate position and the substrate position correction control unit 83 based on the detection of the substrate position By the control, the position correction of the plurality of substrates on the substrate transport path 50 is automatically performed.

  Therefore, it is not necessary for the operator to manually correct the substrate position, and the operation for resuming the operation becomes very simple.

  In particular, in this embodiment, a pair of substrate detection sensors 56a and 56b are provided on the transport shaft 52 for each mounting stage, so that the substrate position can be detected quickly and accurately.

  Further, as the processing for correcting the substrate position based on the detection of the substrate position, the first position correction mode (steps S24 to S26) described above, the first position correction mode according to the state of positional deviation of the printed circuit board 3 on the substrate conveyance path 50, Since the second position correction mode (steps S28 to S30) and the third position correction mode (steps S31 to S34) are selectively executed, a plurality of substrates are moved as much as possible. Thus, the position can be corrected quickly.

  In addition, the specific structure of the mounting machine of this invention is not limited to the said embodiment, A various change is possible.

  For example, one pushing member may be provided for each mounting stage (only the one corresponding to the upstream pushing member 53a). However, if a pair of pushing members is provided as in the above-described embodiment, it is more stable. The printed circuit board can be transported well.

  Further, the number of mounting stages is not limited to four as in the above embodiment, and may be appropriately increased or decreased according to the request.

It is a top view which shows schematic structure of the component mounting machine by one Embodiment of this invention. It is a top view which shows the detailed structure of the said mounting machine. It is the III-III sectional view taken on the line in FIG. It is a figure which shows a board | substrate conveyance apparatus typically, (a) The state before conveyance, (b) is the state at the time of conveyance start, (c) has shown the state of conveyance final stage. It is explanatory drawing which shows arrangement | positioning of the board | substrate detection sensor provided in the conveyance axis | shaft. It is a block diagram which shows the structure of the controller provided in the mounting machine. It is explanatory drawing which shows the board | substrate position detection operation | movement by a pair of board | substrate detection sensor provided in the conveyance axis | shaft. It is a flowchart which shows the specific example of the control performed by the arithmetic processing part of a controller. It is a flowchart which shows the routine of a board | substrate search movement process on a conveyance path. (A) (b) is explanatory drawing which shows the control action by the 1st position correction control mode. (A) (b) is explanatory drawing which shows the control action by the 2nd position correction control mode. (A) (b) is explanatory drawing which shows the control action by the 3rd position correction control mode.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Component mounting machine 3 Printed circuit board 4-7 Mounting stage 8 Loading stage 9 Unloading stage 23 Transfer means 26 Electronic component transfer apparatus 50 Substrate conveyance path 51 Substrate conveyance apparatus 52 Conveyance shaft 53a, 53b Pushing member 56a, 56b Substrate detection sensor 70 Controller (control device)
82 Substrate position detection means 83 Substrate position correction control means

Claims (6)

A plurality of mounting stages that perform mounting work of electronic components on a substrate to be mounted side by side in the substrate transport direction,
Provided on the substrate transport path passing through each mounting stage, and sequentially transports the substrate from the substrate carry-in section on the upstream side of the substrate transport path to the substrate carry-out section on the downstream side of the substrate transport path through the mounting stages. A substrate transfer device capable of simultaneously transferring a plurality of substrates on the road;
A substrate detection sensor provided in the substrate transfer device for detecting a substrate on the substrate transfer path;
A control device for controlling the driving of the substrate transfer device,
The control device
A substrate position detecting means for detecting the position of the substrate on the substrate transport path based on a signal from the substrate detection sensor at the time of restarting operation after a failure due to a cause related to substrate transport;
Substrate position correction control means for controlling the substrate transfer device to drive the substrate to move to the normal position when the substrate position detected by the substrate position detection means is deviated from the normal position. A component mounting machine characterized by that. In the component mounting machine according to claim 1,
The substrate transfer device is
A transport axis extending in the direction of the substrate transport path over each of the mounting stages, and movable in this direction;
A transport shaft driving means for driving the transport shaft;
A plurality of pushing members provided on the carrying shaft for each mounting stage to push the board on the board carrying path of each mounting stage;
A pushing member driving means for changing the position of each pushing member between a board pushing position where the board can be pushed along with the movement of the transport shaft and a retracted position away from the board;
A component mounting machine, wherein a substrate detection sensor is provided on the transport shaft. In the component mounting machine according to claim 2,
The transport axis can be reciprocated in the direction of the substrate transport path within a movable range corresponding to one stage of the mounting stage.
The component mounting machine, wherein the board detection sensor is provided for each mounting stage at a pitch corresponding to the length between the mounting stages. In the component mounting machine according to claim 3,
A pair of board detection sensors are provided for each mounting stage, and a distance between the pair of board detection sensors is adjusted to be substantially the same as the length of the board. In the component mounting machine of any one of Claims 2-4,
A pair of the pushing members are provided for each mounting stage, and a pair of pushing members are provided so that the pair of pushing members can transport the substrate on the substrate transport path from both the upstream side and the downstream side. A component mounting machine in which the interval between members is adjusted. In the component mounting machine according to claim 5,
The control means for correcting the substrate position is a control for moving the substrate to a normal position, with all of the pair of pressing members provided for each mounting stage being set to the substrate pressing position on the substrate transport path. The first position correction control mode for moving the substrate in a batch and the substrate on the substrate transport path in a state where only the upstream push member is set to the substrate push position for all pairs of push members And a third position correction control mode in which the substrate on the substrate transport path is individually moved in a state where only the pressing members corresponding to some mounting stages are set to the substrate pressing position. Is selectively executed according to the state of positional deviation of the board on the board conveyance path.

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