JP2017118007A - Component supply device and component supply method - Google Patents

Abstract

A component supply apparatus and a component supply method capable of preventing erroneous supply of components due to attachment / detachment of a carrier tape from a tape feeder during power-off. A tape feeder (part supply device) detects a first sensor (S1), a second sensor (S2), and a third sensor (S3) (detection unit) that detect the presence or absence of a carrier tape in a conveyance path. Based on the change in the presence or absence of the carrier tape, a mode designation unit 21a (designation unit) that designates the carrier tape transport mode by the exchange flag 41c (flag), and the presence or absence of the detected carrier tape and the designated exchange flag 41c A feeder storage unit 41 (storage unit) that stores information on the parts stored in the carrier tape to be conveyed, and the power supplied to the tape feeder 8 based on the presence / absence of the detected carrier tape and the designated replacement flag 41c. An operation determination unit 21b (determination unit) that determines a recovery processing operation when the power is turned on again is provided. [Selection] Figure 6

Description

  The present invention relates to a component supply apparatus and a component supply method for pitch-feeding a carrier tape containing components.

  A tape feeder is known as a component supply device in a component mounting apparatus. The tape feeder feeds components to the component take-out position by the mounting head of the component mounting mechanism by pitch-feeding the carrier tape holding the components, and a plurality of slots are provided in the component supply section of the component mounting apparatus. Tape feeders are arranged side by side. The carrier tape is supplied in a state of being wound and stored on the supply reel, and the operator reads the barcode attached to the supply reel to confirm that it is a part to be supplied, and then is supplied to the tape feeder. (For example, refer to Patent Document 1). As a result, information such as the type and quantity of parts held by the tape feeder and the carrier tape supplied to the tape feeder is linked.

  When the type of the mounting board to be produced is changed, so-called changeover is performed in which a component to be mounted on the next mounting board to be produced is prepared so as to be supplied from the component supply unit. In the setup change, a tape feeder that supplies a component that is not mounted on a mounting board to be produced next is removed from the component supply unit, and another tape feeder that supplies a component mounted in an empty slot is attached. The removed tape feeder is stored in a state where it is attached to another component mounting apparatus or attached to a storage cart or the like.

Japanese Patent No. 4846628

  Incidentally, the prior art including Patent Document 1 has the following problems when the tape feeder is removed from the component mounting apparatus and stored. That is, when the power supply is cut off from the component mounting apparatus, attachment / detachment of the carrier tape to / from the tape feeder is not recorded. Therefore, even if another carrier tape is accidentally installed after the carrier tape has been removed from the tape feeder with the power turned off, the component mounting device will store the associated information stored before the power is turned off. There is a risk that an incorrect component is mounted on the board because of the production based on this.

  Accordingly, an object of the present invention is to provide a component supply apparatus and a component supply method that can prevent erroneous supply of components due to the carrier tape being attached to and detached from the tape feeder during power-off.

  A component supply device according to the present invention is a component supply device that transports a carrier tape covered with a cover tape and covered with a cover tape to a component removal position and supplies the stored component to a component mounting device. A main body portion provided with a conveyance path for guiding the carrier tape from the insertion port to the discharge port for discharging the carrier tape, and a carrier tape conveyance unit that conveys the carrier tape and conveys the stored components to the component pick-up position. A detection unit for detecting the presence or absence of a carrier tape in the conveyance path, a designation unit for designating the carrier tape conveyance mode by a flag based on the change in the presence or absence of the detected carrier tape, and the detected The presence / absence of a carrier tape, the designated flag, and the components stored in the carrier tape mounted on the component supply device A storage unit for storing information, and a determination unit for determining a processing operation when power supplied to the component supply device is turned on again based on the presence or absence of the detected carrier tape and the specified flag. Prepare.

  The component supply method of the present invention is a component supply device that transports a carrier tape covered with a cover tape and covered with a cover tape to a component removal position and supplies the stored component to a component mounting device. , A main body provided with a conveyance path for guiding the carrier tape from an insertion port for inserting the carrier tape to a discharge port for discharging the carrier tape, and conveying the carrier tape to convey the stored component to a component removal position A carrier tape transport unit, and a detection unit that detects the presence or absence of a carrier tape in the transport path, detects the presence or absence of a carrier tape in the transport path, and based on the change in the presence or absence of the detected carrier tape, The carrier tape transport mode is designated by a flag, the presence / absence of the detected carrier tape and the designated tape are designated. And information on the components stored in the carrier tape mounted on the component supply device, and the power supplied to the component supply device is restored based on the presence or absence of the detected carrier tape and the specified flag. Determines the processing operation when it is entered.

  According to the present invention, it is possible to prevent erroneous supply of components due to the carrier tape being detached from the tape feeder while the power is shut off.

Configuration explanatory diagram of a component mounting system according to an embodiment of the present invention The top view of the component mounting apparatus of one embodiment of this invention The fragmentary sectional view of the component mounting apparatus of one embodiment of the present invention Structure explanatory drawing of the tape feeder of one embodiment of this invention (A) (b) (c) Functional explanatory drawing of the shutter mechanism provided in the tape feeder of one embodiment of the present invention The block diagram which shows the structure of the control system of (a) component mounting system of one embodiment of this invention (b) The control system of a tape feeder (A) Configuration explanation diagram of component arrangement data used in the component mounting system of one embodiment of the present invention (b) Configuration explanation diagram of feeder information (A) (b) (c) Carrier tape replacement process and replacement flag process explanatory diagram in the tape feeder of one embodiment of the present invention The flowchart which shows the component supply method of one embodiment of this invention The flowchart which shows the process which memorize | stores the tape feeder state before power-off in the component supply method of one embodiment of this invention The flowchart which shows the processing operation after power-on again in the component supply method of one embodiment of this invention The flowchart which shows the recovery processing operation | movement in the components supply method of one embodiment of this invention (A) (b) The figure explaining determination of the recovery processing operation | movement in the component supply method of one embodiment of this invention (A) (b) The figure explaining determination of the recovery processing operation | movement in the component supply method of one embodiment of this invention (A) (b) The figure explaining determination of the recovery processing operation | movement in the component supply method of one embodiment of this invention (A) (b) The figure explaining determination of the recovery processing operation | movement in the component supply method of one embodiment of this invention (A) (b) The figure explaining determination of the recovery processing operation | movement in the component supply method of one embodiment of this invention

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. The configuration, shape, and the like described below are illustrative examples, and can be appropriately changed according to the specifications of the component mounting system. Below, the same code | symbol is attached | subjected to the element which respond | corresponds in all the drawings, and the overlapping description is abbreviate | omitted. In FIG. 2 and a part to be described later, as a biaxial direction orthogonal to each other in a horizontal plane, an X direction (horizontal direction in FIG. 2) of the substrate transport direction and a Y direction (front-back direction in FIG. 2) orthogonal to the substrate transport direction. Is shown. In FIG. 3 and a part to be described later, the Z direction is shown as the height direction orthogonal to the horizontal plane. The Z direction is the vertical direction or the orthogonal direction when the component mounting system is installed on a horizontal plane.

  First, a component mounting system will be described with reference to FIG. In FIG. 1, a component mounting system 1 is configured such that a printing device M1, component mounting devices M2 to M4, and a reflow device M5 are connected and connected by a communication network 2, and the whole is controlled by a management computer 3. Yes. The component mounting system 1 has a function of mounting a component on a substrate and manufacturing a mounting substrate.

  The printing apparatus M1 screen-prints paste-like solder on the component bonding electrodes formed on the substrate. The component mounting apparatuses M <b> 2 to M <b> 4 perform a component mounting operation in which components are taken out by a mounting head from a parts feeder such as a tape feeder arranged in a component supply unit, and transferred and mounted on a substrate. Thereafter, the substrate after the component mounting is sent to the reflow apparatus M5, and the mounting substrate is manufactured by soldering the component mounted on the substrate to the substrate.

  Next, the configuration of the component mounting apparatuses M2 to M4 will be described with reference to FIGS. FIG. 3 partially shows an AA cross section in FIG. The component mounting apparatuses M2 to M4 have a function of mounting the components supplied from the component supply means on the board. In FIG. 2, a substrate transport mechanism 5 is disposed in the center of the base 4 in the X direction. The board transport mechanism 5 transports the board 6 carried in from the upstream side, and positions and holds the board 6 on a mounting stage set for executing a component mounting operation. Component supply units 7 are arranged on both sides of the substrate transport mechanism 5, and a plurality of tape feeders 8 are mounted in parallel on each component supply unit 7. The tape feeder 8 feeds components to a component pick-up position by a mounting head of a component mounting mechanism described below by pitch-feeding the carrier tape containing the components in the tape feeding direction.

  A Y-axis moving table 9 having a linear drive mechanism is disposed at one end in the X direction on the upper surface of the base 4. Similarly, two X-axis movement tables 10 each having a linear drive mechanism are coupled to the Y-axis movement table 9 so as to be movable in the Y direction. A mounting head 11 is mounted on each of the two X-axis moving tables 10 so as to be movable in the X direction. The mounting head 11 is a multiple mounting head having a plurality of holding heads 11a, and the lower end of each holding head 11a, as shown in FIG. A suction nozzle 11b is mounted.

  By driving the Y-axis movement table 9 and the X-axis movement table 10, the mounting head 11 moves in the X direction and the Y direction. As a result, the two mounting heads 11 pick up and hold the components by the suction nozzle 11b from the component pick-up positions of the tape feeders 8 arranged in the corresponding component supply sections 7, respectively, and are positioned on the substrate transport mechanism 5. Transfer and mount at 6 mounting points. The Y-axis moving table 9, the X-axis moving table 10 and the mounting head 11 constitute a component mounting mechanism 12 that moves and mounts the component on the substrate 6 by moving the mounting head 11 holding the component.

  A component recognition camera 13 is disposed between the component supply unit 7 and the board transport mechanism 5. When the mounting head 11 that picks up the component from the component supply unit 7 moves above the component recognition camera 13, the component recognition camera 13 captures the component held in the mounting head 11 and recognizes the holding posture of the component. To do. A substrate recognition camera 14 that moves integrally with the mounting head 11 is mounted on the lower surface of the X-axis moving table 10.

  As the mounting head 11 moves, the substrate recognition camera 14 moves above the substrate 6 positioned by the substrate transport mechanism 5 and images the substrate 6 to recognize the state of the substrate 6. In the component mounting operation on the substrate 6 by the mounting head 11, the mounting position correction is performed in consideration of the component recognition result by the component recognition camera 13 and the substrate recognition result by the substrate recognition camera 14.

  As shown in FIG. 3, a carriage 15 in which a plurality of tape feeders 8 are mounted in advance on a feeder base 15 a is set in the component supply unit 7. The feeder base 15a is set with a feeder address for specifying the feeder position where the individual tape feeder 8 is mounted. In the component mounting operation, each tape in the feeder base 15a is set via the feeder address. The feeder 8 is specified.

  The position of the carriage 15 is fixed in the component supply unit 7 by clamping the feeder base 15a to the base 4 by a clamp mechanism (not shown). The carriage 15 holds a supply reel 17 for storing a carrier tape 16 holding components in a wound state. The carrier tape 16 pulled out from the supply reel 17 is pitch-fed by the tape feeder 8 to the component take-out position by the suction nozzle 11b.

  A bar code label L (identification information) is affixed to each supply reel 17 in advance, and the bar code label L is read by the bar code reader R during the component supply operation. The read result is transmitted to the management computer 3 via the wireless receiver 51, and further transmitted from the management computer 3 to the component mounting apparatuses M2 to M4 and from the component mounting apparatuses M2 to M4 to the tape feeder 8 (see FIG. 6). Thus, the barcode reader R serves as a reading unit that reads the identification information attached to the reel on which the carrier tape 16 is wound and stored.

  Next, the configuration and function of the tape feeder 8 will be described with reference to FIG. The tape feeder 8 (component supply device) has a function of transporting a carrier tape 16 that contains components and covered with a cover tape to a component removal position and supplies the stored components to the component mounting devices M2 to M4. Yes. As shown in FIG. 4, the tape feeder 8 includes a main body 8a and a mounting portion 8b protruding downward from the lower surface of the main body 8a. In a state where the tape feeder 8 is mounted with the lower surface of the main body portion 8a aligned with the feeder base 15a, the tape feeder 8 is fixedly mounted on the component supply unit 7 and is incorporated to control tape feeding in the tape feeder 8. The feeder control unit 21 is electrically connected to the device control unit 22 of the component mounting apparatuses M2 to M4.

  Inside the main body 8a, there is provided a tape transport path 8c for guiding the carrier tape 16 drawn from the supply reel 17 and taken into the main body 8a. The tape transport path 8c is a discharge port that opens downstream from the component take-out position where the component is taken out by the mounting head 11 from the insertion port 8d into which the carrier tape 16 opened at the upstream end in the tape feeding direction is inserted in the main body 8a. 8e is communicated. That is, the main body 8a is provided with a tape transport path 8c (transport path) for guiding the carrier tape 16 from the insertion port 8d for inserting the carrier tape 16 to the discharge port 8e for discharging the carrier tape 16. In the process of continuously executing the component mounting operation, a plurality of carrier tapes 16 are sequentially inserted from the insertion port 8d and supplied to the tape feeder 8.

  The tape feeder 8 shown in the present embodiment is a splicing-less method (automatic loading method) in which two carrier tapes 16 fed one after the other are sequentially inserted and supplied to the insertion port 8d while being separated from each other. Is adopted. Therefore, the tail end E of the carrier tape 16 (1) (hereinafter abbreviated as “preceding tape 16 (1)”) that is already mounted on the tape feeder 8 and is subject to component removal by the mounting head 11, and when the component runs out. It is not necessary to join the leading end T of the newly added carrier tape 16 (2) (hereinafter abbreviated as “subsequent tape 16 (2)”) with a joining tape.

  The insertion slot 8d is provided with a sprocket 24C with which the subsequent tape 16 (2) to be additionally mounted is engaged. The sprocket 24C has a function of preventing the trailing tape 16 (2) from dropping off by the built-in one-way clutch mechanism 25 regulating the tape feeding direction of the trailing tape 16 (2). A shutter mechanism 30 is disposed on the downstream side of the sprocket 24C. The shutter mechanism 30 is inserted from the insertion port 8d by moving the shutter 32a (see FIG. 5) of the shutter driving member 32 up and down with respect to the guide member 31 fixed to the frame portion 8f constituting the main body portion 8a. The carrier tape 16 has a function of permitting / prohibiting entry of the carrier tape 16 into the downstream tape transport path 8c.

  In FIG. 4, a first tape feeding mechanism 23A and a second tape feeding mechanism for feeding the preceding tape 16 (1) and the succeeding tape 16 (2) to the downstream side and the upstream side in the tape transport path 8c. 23B is provided. The second tape feeding mechanism 23B provided on the upstream side has a function of continuously feeding the newly attached subsequent tape 16 (2) from the insertion port 8d side to the first tape feeding mechanism 23A side. The sprocket 24B is rotationally driven by the second motor E2. The sprocket 24B incorporates an encoder 26 as rotation detection means, and the detected rotation detection signal is transmitted to the feeder controller 21.

  A tape pressing mechanism 27 and a tape stopper mechanism 28 are disposed below the second tape feeding mechanism 23B. The succeeding tape 16 (2) inserted from the insertion port 8d is pressed against the sprocket 24B by the tape pressing mechanism 27 and engages with the sprocket 24B so that the tape can be fed by the second tape feeding mechanism 23B. Become. The tape stopper mechanism 28 passes the downstream side of the preceding tape 16 (1) without stopping, and the leading end T of the succeeding tape 16 (2) newly inserted with the preceding tape 16 (1) attached. Is temporarily stopped by the stopper member 28a.

  The first tape feed mechanism 23A provided on the downstream side has a function of pitch-feeding the preceding tape 16 (1) to the component pick-up position by the mounting head 11 at a predetermined feed pitch, and the sprocket 24A is first fed. The motor E1 is rotationally driven. Above the first tape feeding mechanism 23A, a pressing member 29 has a function of pressing the leading tape 16 (1) from above and peeling the cover tape to expose the components stored in the leading tape 16 (1). It is installed.

  The components that have been pitch-fed to the component extraction position 29 a are picked up by vacuum suction by the suction nozzle 11 b of the mounting head 11 through the component extraction opening formed in the pressing member 29. Thus, the first tape feeding mechanism 23A and the second tape feeding mechanism 23B serve as a carrier tape transport unit that transports the carrier tape 16 and transports the stored components to the component take-out position 29a.

  In FIG. 4, a first detection position P1 for detecting the carrier tape 16 is set on the upstream side of the first tape feeding mechanism 23A in the tape transport path 8c. Similarly, a second detection position P2 for detecting the carrier tape 16 is set downstream of the second tape feeding mechanism 23B and upstream of the first detection position P1. The first sensor S1 and the second sensor S2 respectively disposed at the first detection position P1 and the second detection position P2 are carrier tapes 16 (at the first detection position P1 and the second detection position P2). The presence or absence of the preceding tape 16 (1) and the succeeding tape 16 (2)) is detected.

  Further, the tape stopper mechanism 28 is provided with a third sensor S3 for detecting that the succeeding tape 16 (2) is in contact with the stopper member 28a. That is, the third sensor S3 detects the presence / absence of the succeeding tape 16 (2) at the position of the stopper member 28a (third detection position P3). As described above, the first sensor S1, the second sensor S2, and the third sensor S3 are detection units that detect the presence or absence of the carrier tape 16 in the tape transport path 8c (transport path). Hereinafter, for convenience, the first sensor S1, the second sensor S2, and the third sensor S3 are simply referred to as a sensor S1, a sensor S2, and a sensor S3, respectively. Further, the first detection position P1, the second detection position P2, and the third detection position P3 are simply referred to as a detection position P1, a detection position P2, and a detection position P3, respectively.

  The detection results from the sensors S1, S2, and S3 are transmitted to the feeder controller 21. The feeder control unit 21 controls the first tape feeding mechanism 23A and the second tape feeding mechanism 23B based on these detection results and the rotation detection result by the encoder 26. Thereby, the tape feeding operation of the preceding tape 16 (1) and the succeeding tape 16 (2) in the tape feeder 8 is executed according to a predetermined control pattern.

  In FIG. 4, an operation / display panel 40 connected to the feeder controller 21 is disposed on the upper surface on the upstream side of the tape feeder 8. The operation / display panel 40 includes an operation button for operating a tape feeding operation and a tape returning operation by the first tape feeding mechanism 23A and the second tape feeding mechanism 23B, and an operation for opening and closing the shutter in the shutter mechanism 30. Various operation buttons such as a button and an input button for writing a component ID to the built-in memory of the tape feeder 8 are provided. Further, the operation / display panel 40 is provided with a notification lamp for performing notification about a predetermined item set in advance.

  Next, the configuration and function of the shutter mechanism 30 provided in the tape feeder 8 will be described with reference to FIG. In FIG. 5A, the guide member 31 is fixed to the frame portion 8f so that the guide surface 31a is aligned with the tape feed height at which the carrier tape 16 inserted from the insertion port 8d is fed. The guide surface 31a of the guide member 31 is set to a shape capable of supporting and guiding the carrier tape 16 from the lower surface side.

  Above the guide member 31, a shutter drive member 32 having a downstream end portion pivotally supported by a shaft support portion 33 is disposed in a substantially horizontal posture. A shutter 32a bent downward is provided at the upstream end of the shutter drive member 32. When the shutter drive member 32 rotates around the shaft support portion 33, the lower end portion of the shutter 32a has a guide surface 31a. It is free to touch.

  Above the shutter drive member 32, a solenoid 34 that is excited and driven by the feeder controller 21 is disposed in a posture in which the drive shaft 34a protrudes downward. The drive shaft 34a is coupled to the shutter drive member 32 in a form capable of transmitting an upward drive force. Further, the shutter drive member 32 is urged downward (arrow a) by a spring member 35 disposed on the upper surface. When the solenoid 34 shown in FIG. 5A is in a non-excited state (non-energized state), the driving force of the solenoid 34 does not act on the shutter drive member 32. Therefore, the shutter mechanism 30 is in a closed state in which the shutter 32a is in contact with the guide surface 31a by the urging force of the spring member 35. In this state, the carrier tape 16 inserted from the insertion port 8d is prohibited from entering downstream by the shutter 32a in contact with the guide surface 31a.

  FIG. 5B shows a state (energized state) in which the solenoid 34 is excited by the feeder control unit 21 and the drive shaft 34a is moved upward (arrow b). As a result, the shutter driving member 32 is displaced upward, a predetermined clearance C is secured between the lower end of the shutter 32a and the guide surface 31a of the guide member 31, and the shutter mechanism 30 is opened. In this state, the carrier tape 16 inserted from the insertion port 8d is allowed to enter the downstream side through the clearance C. Thus, in the state in which the preceding tape 16 (1) is inserted from the insertion port 8d and fed to the tape transport path 8c, the subsequent tape 16 (2) is further overlapped via the clearance C between the shutter 32a and the guide surface 31a. Can be inserted.

  FIG. 5C shows a case where the power supply is turned off while the preceding tape 16 (1) is supplied and the power supply is turned off. In this case, since the solenoid 34 is in a non-excited state, the shutter driving member 32 is pushed down by the spring member 35 (arrow c), and the shutter 32a is in contact with the upper surface of the preceding tape 16 (1). . In such a state, even if the subsequent tape 16 (2) is to be inserted through the insertion port 8d, the insertion of the subsequent tape 16 (2) is suppressed by the shutter 32a in the closed state.

  The solenoid 34 is controlled in an excited state and a non-excited state by the feeder control unit 21 that receives a command from the component mounting apparatuses M2 to M4, a calculation result by the internal processing unit, an operation of the operator / operation of the display panel 40, and the like. The In this way, the tape feeder 8 (part supply device) is driven by the tape feeder 8 in the opening and closing direction, and the insertion of the carrier tape 16 into the insertion port 8d is suppressed in the closed state and allowed in the open state. ) Having a shutter mechanism 30 (shutter portion).

  Next, the configuration of the control system of the component mounting system 1 will be described with reference to FIG. The component mounting system 1 includes a tape feeder 8 (component supply device) and component mounting devices M2 to M4. 6A shows the overall configuration of the component mounting system 1, and FIG. 6B shows the configuration of a plurality of tape feeders 8 mounted on the component supply units 7 of the component mounting apparatuses M2 to M4.

  In FIG. 6A, the management computer 3 is connected to the component mounting apparatuses M <b> 2 to M <b> 4 through the communication network 2. The management computer 3 includes a wireless reception device 51 that receives a signal from a portable terminal such as a barcode reader R. The storage unit 3a included in the management computer 3 stores various data such as production data used for component mounting work by the component mounting apparatuses M2 to M4. In the component mounting work, production data is downloaded from the management computer 3 and stored in the device storage unit 52 of the component mounting devices M2 to M4, and operation information of the component mounting devices M2 to M4 is collected by the management computer 3. The barcode reader R may be connected to each of the component mounting apparatuses M2 to M4 by wire.

  The device control unit 22 included in the component mounting apparatuses M2 to M4 is an arithmetic processing device including a CPU function. By executing a processing program stored in the device storage unit 52, the component mounting mechanism 12, the component supply unit 7, Each part of the display unit 18 is controlled. The component mounting apparatuses M2 to M4 include a feeder specifying unit 53 and an update processing unit 54 that are information processing units. In the control process by the apparatus control unit 22, various production data such as mounting data 52a and component arrangement data 52b stored in the apparatus storage unit 52 are referred to.

  The mounting data 52a is data such as the component type of the component to be mounted and the mounting position coordinates of the board, and is stored for each board type to be produced. The component arrangement data 52 b is data defining the feeder address of the tape feeder 8 in the component supply unit 7 and the component ID of the carrier tape 16 mounted on the tape feeder 8.

  Here, an example of the component arrangement data 52b will be described with reference to FIG. FIG. 7A shows the component arrangement data 52b of the component supply unit 7 mounted on the tape feeder 8 capable of supplying up to two carrier tapes 16. Corresponding to each feeder address 61, the component arrangement data 52b stores a feeder ID 62 for specifying the tape feeder 8 attached to the feeder address 61. Further, a part ID 63 (1) of the carrier tape 16 that becomes the preceding tape 16 (1) and a part ID 63 (2) of the carrier tape 16 that becomes the subsequent tape 16 (2) are stored.

  In FIG. 7 (a), the tape feeder 8 with the feeder ID 62 installed at the position f1 and the feeder ID 62 with Faaaa has two carrier tapes 16 mounted thereon, and the component ID 63 (1) and the component ID 63 (2). The part ID 63 is stored in both. Further, the tape feeder 8 with the feeder address 61 being f2 and the feeder ID 62 being Fbbbb is loaded with one carrier tape 16, the component ID 63 is stored in the component ID 63 (1), and the component ID 63 (2) is empty ( “-” In the figure). Further, the tape feeder 8 having the feeder address 61 of f3 and the feeder ID 62 of Fcccc is not loaded with the carrier tape 16, and both the component ID 63 (1) and the component ID 63 (2) are empty.

  In FIG. 6A, the feeder specifying unit 53 specifies the feeder ID 62 and the feeder address 61 of the tape feeder 8 in which the supply operation of the carrier tape 16 is detected. The update processing unit 54 performs an update process for updating the component arrangement data 52b based on the component ID 63 read by the barcode reader R when the carrier tape 16 is normally supplied to the tape feeder 8.

  Here, the configuration example in which the feeder specifying unit 53 and the update processing unit 54 are the processing functions of the component mounting apparatuses M2 to M4 is shown, but these processing functions may be provided as the processing functions of the management computer 3. Good. The display unit 18 displays various screens required for executing the component mounting work by the component mounting apparatuses M2 to M4.

  Next, the configuration of the control system of the tape feeder 8 will be described. In FIG. 6B, the feeder controller 21 provided in the tape feeder 8 controls the first tape feeding mechanism 23 </ b> A, the second tape feeding mechanism 23 </ b> B, and the solenoid 34 of the shutter mechanism 30. This control is performed based on a control signal from the component mounting apparatuses M2 to M4, an operation input from the operation / display panel 40, and signals from the encoder 26, sensor S1, sensor S2, and sensor S3 built in the sprocket 24B. . The feeder control unit 21 is connected to the device control unit 22 of the component mounting apparatuses M <b> 2 to M <b> 4 via the communication unit 42.

  In the control process by the feeder control unit 21, various data such as feeder information 41a, detection information 41b, and replacement flag 41c stored in the feeder storage unit 41 provided in the tape feeder 8 are referred to. Here, an example of the feeder information 41a will be described with reference to FIG. FIG. 7B shows the feeder information 41a in the tape feeder 8 capable of supplying up to two carrier tapes 16. The feeder information 41a stores the component ID 63 of the carrier tape 16 attached to the tape feeder 8.

  In the tape feeder 8 on which the two carrier tapes 16 are mounted, the component ID 63 is stored in both the component ID 63 (1) of the preceding tape 16 (1) and the component ID 63 (2) of the subsequent tape 16 (2). . In the tape feeder 8 to which one carrier tape 16 is attached, the component ID 63 is stored only for the component ID 63 (1), and the component ID 63 (2) is empty. In the tape feeder 8 to which the carrier tape 16 is not mounted, both the component ID 63 (1) and the component ID 63 (2) are empty. The feeder information 41a of FIG. 7B is the feeder information 41a of the tape feeder 8 with the feeder ID 62 of Faaaa in the component arrangement data 52b shown in FIG. 7A.

  In FIG. 6B, the detection information 41b is information on the presence / absence of the carrier tape 16 in the tape transport path 8c determined by the feeder control unit 21 based on the detection results of the sensors S1, S2, and S3. The replacement flag 41c indicates whether or not the “replacement transport mode WR” in which the tape feeder 8 transports while replacing the carrier tape 16 is in progress.

  The feeder control unit 21 includes a mode specifying unit 21a and an operation determining unit 21b as internal processing functions. The mode designating unit 21a determines the transport mode of the carrier tape 16 based on the change in the presence or absence of the carrier tape 16 detected by the sensors S1, S2, and S3 included in the detection information 41b, and the transport mode of the carrier tape 16 This is a designation unit that is designated by a replacement flag 41c (flag). Based on the presence / absence of the detected carrier tape 16 (detection information 41b) and the designated replacement flag 41c, the operation determination unit 21b performs the operation when the power supplied to the tape feeder 8 (component supply device) is turned on again. It is a determination part which determines a processing operation.

  Thus, the feeder storage unit 41 (storage unit) includes detection information 41b that is information on the presence or absence of the detected carrier tape 16, and a replacement flag 41c (flag) specified by the mode specification unit 21a (designation unit). The feeder information 41a for storing the component ID 63, which is information on the components stored in the carrier tape 16 mounted on the tape feeder 8, is stored.

  Next, the replacement process of the replacement flag 41c and the carrier tape 16 in the automatic loading type tape feeder 8 will be described with reference to FIG. The mode designating unit 21a determines the carrier tape conveyance mode in the tape feeder 8 based on the change in the detection information 41b, and designates the replacement flag 41c that indicates the conveyance mode. The feeder controller 21 controls the conveyance of the carrier tape 16 in the tape conveyance path 8c according to the conveyance mode indicated by the replacement flag 41c. The tape feeder 8 is in the “replacement transport mode WR” when the replacement flag 41c is on, and is in the “normal transport mode WN” when it is off.

  FIG. 8A shows the state of the tape feeder 8 in the “normal transport mode WN” with the replacement flag 41c set to OFF. The preceding tape 16 (1) is transported so that the parts accommodated by the first tape feeding mechanism 23A are pitch-fed (arrow e) to the parts take-out position 29a. The succeeding tape 16 (2) inserted (arrow f) from the insertion port 8d for replenishing parts is engaged with the sprocket 24B of the second tape feeding mechanism 23B, and the leading end T is the tape stopper mechanism 28. It stops in contact with the stopper member 28a. At the component removal position 29a, the component is removed by the mounting head 11 (holding head 11a).

  When the component supply from the preceding tape 16 (1) proceeds and the trailing end E of the preceding tape 16 (1) reaches the detection position P2 as shown in FIG. 8B, the trailing end E is detected by the sensor S2. Detected. That is, when the carrier tape 16 detected at the detection position P2 changes from presence to absence, the mode designation unit 21a changes the replacement flag 41c from off to on. As a result, the tape feeder 8 enters the “replacement transport mode WR”.

  In the “replacement transport mode WR”, the feeder control unit 21 controls the first tape feeding mechanism 23A and the second tape feeding mechanism 23B based on a preset control pattern. That is, the succeeding tape 16 (2) released from the temporary stop by the stopper member 28a is fed in a state where the distance from the preceding tape 16 (1) is maintained. Then, as shown in FIG. 8C, when the preceding tape 16 (1) that has finished supplying the components is discharged from the discharge port 8e (arrow g), the subsequent tape 16 (2) is pitch-fed to the component removal position 29a. The parts are ready for supply.

  As described above, when the component supply carrier tape 16 is switched from the preceding tape 16 (1) to the subsequent tape 16 (2) and preparation for component supply by the subsequent tape 16 (2) is completed, the mode designating unit 21a displays the replacement flag. 41c is changed from on to off. That is, when the carrier tape 16 detected at the detection position P1 changes from presence to absence and further changes to presence, the mode designating unit 21a designates the replacement flag 41c to change from on to off. As a result, the “replacement transport mode WR” shifts to the “normal transport mode WN”.

  By the way, at the time of setup change to change the mounted substrate to be produced, the tape feeder 8 that is not used for the next production may be removed from the component supply unit 7 and stored in a storage cart or the like. Alternatively, the entire carriage 15 may be removed from the parts supply unit 7 and replaced with the next production carriage 15 in a batch. In this manner, while being removed from the component supply unit 7 and stored, the carrier tape 16 may fall off from the tape feeder 8 or a different carrier tape 16 may be inserted by mistake.

  However, since the power supplied to the tape feeder 8 is cut off in the state of being removed from the component supply unit 7, attachment / detachment of the carrier tape 16 from the tape feeder 8 is not recorded. Therefore, when the tape feeder 8 is attached to the component supply unit 7 again and the power is turned on again, there is no change in the state of the carrier tape 16 attached to the tape feeder 8 before and after the power is turned off. A restart process described later is performed for the purpose of confirmation and recovery when there is a change.

  Next, with reference to FIGS. 9 to 12, the processing operation when the power supplied to the tape feeder 8 (component supply device) of the automatic loading system in the component mounting system 1 of the present embodiment is turned on again is determined. A component supply method will be described. In FIG. 9, detection information 41b and a replacement flag 41c are stored in the feeder storage unit 41 as the state of the carrier tape 16 attached to the tape feeder 8 before the power is cut off (ST1: state storage before power off) Process). Thereafter, the power supply to the tape feeder 8 is shut off by removal from the component supply unit 7 (ST2). Next, when the power is reapplied to the tape feeder 8 by re-attachment to the component supply unit 7 or the like (ST3), a restart process is performed when the power is reapplied in the tape feeder 8 (ST4: Start-up process).

  Next, with reference to FIG. 10, the details of the pre-power-off state storing step (ST1) will be described. In the tape feeder 8, if there is a change in the detection results of the sensors S1, S2, and S3 provided in the tape transport path 8c (Yes in ST11), the presence / absence of the carrier tape 16 in the detection information 41b is updated and stored in the feeder. Stored in unit 41 (ST12). Next, whether the mode designation unit 21a changes the transport mode of the carrier tape 16 between the “replacement transport mode WR” and the “normal transport mode WN” based on the change in the detection information 41b (the presence or absence of the carrier tape 16). It is determined whether or not (ST13).

  If it is determined that the transport mode is to be changed (Yes in ST13), the mode designating unit 21a designates the replacement flag 41c and stores it in the feeder storage unit 41 (ST14). If it is determined that the transport mode is not changed (No in ST13), the mode designating unit 21a does not change the replacement flag 41c, and the pre-power-off state storing step (ST1) is ended. As described above, before the power is cut off, the tape feeder 8 (component supply device) detects the presence or absence of the carrier tape 16 in the tape conveyance path 8c (conveyance path), and detects the detected change in the presence or absence of the carrier tape 16. Based on this, the transport mode of the carrier tape 16 is designated by the exchange flag 41c (flag), and the presence / absence of the detected carrier tape 16 and the designated exchange flag 41c are stored.

  Note that the state storage step before power shutoff (ST1) may be performed repeatedly while the tape feeder 8 is powered on, or may be performed when the power is shut off (immediately before). In addition, when the power is shut off, feeder information 41 a including a component ID 63 (component information) of a component stored in the carrier tape 16 mounted on the tape feeder 8 (component supply device) is also stored in the feeder storage unit 41. Has been.

  Next, details of the restart processing step (ST4) will be described with reference to FIG. First, when the power is re-supplied (conducted) to the tape feeder 8 (ST3), the presence or absence of the carrier tape 16 is detected by the sensors S1, S2, and S3 (ST21: detection step after power re-on). Next, a recovery processing operation is determined by the operation determination unit 21b based on the detection information 41b stored before the power is shut off, the replacement flag 41c, and the presence / absence of the carrier tape 16 detected after the power is turned on again. Is executed (ST22: recovery processing step). That is, the recovery processing when the power supplied to the tape feeder 8 (component supply device) is turned on again by the operation determination unit 21b based on the detected presence or absence of the carrier tape 16 and the designated replacement flag 41c (flag). The action is determined.

  Next, details of the recovery processing step (ST22) will be described with reference to FIGS. First, the operation determining unit 21b determines the presence / absence of the carrier tape 16 in the detection information 41b stored in the pre-power-off state storing step (ST1) and the presence / absence of the carrier tape 16 detected in the post-power-on detection step (ST21). Compare (ST31: tape presence / absence comparison step). That is, the presence or absence of the carrier tape 16 detected by the sensor S1, sensor S2, sensor S3 (detection unit) stored when the power is cut off, and the sensor S1, sensor S2, sensor when the power is turned on again It is compared whether or not the presence or absence of the carrier tape 16 detected in S3 matches. At this time, the presence or absence of the carrier tape 16 is compared at each of the detection position P1, the detection position P2, and the detection position P3.

  If the presence / absence of the carrier tape 16 matches in the tape presence / absence comparison step (ST31) (Yes), it is determined that the carrier tape 16 has not been attached / detached before and after the power is turned off, and the component supply operation is resumed. In other words, the operation determination unit 21b determines to restart the component supply operation as the recovery processing operation.

  If the presence / absence of the carrier tape 16 before and after the power shutoff does not match in the tape presence / absence comparison step (ST31) (No), whether or not the replacement flag 41c stored in the pre-power-off state storage step (ST1) is on. Is confirmed (ST32: flag confirmation step). That is, the operation determining unit 21b determines whether or not the stored replacement flag 41c (flag) indicates that the plurality of carrier tapes 16 are in the “replacement transport mode WR” in which the plurality of carrier tapes 16 are transported (whether the replacement flag 41c is on). Confirm).

  When the replacement flag 41c is on in the flag confirmation step (ST32) (Yes), it is determined that the carrier tape 16 has dropped from the tape feeder 8, and the following processing is performed. That is, before the power is shut off, the preceding tape 16 (1) and the succeeding tape 16 (2) shown in FIG. 13 (a) are in a conveying state, and after the power is turned on again, the upstream sensor S2 is shown in FIG. 13 (b). Thus, when it turns off and does not agree before and after power-off, it is determined that the subsequent tape 16 (2) has dropped from the insertion slot 8d. Then, the component ID 63 (2) of the subsequent tape 16 (2) is deleted from the feeder information 41a, and the replacement flag 41c is updated to OFF (ST33).

  Further, the leading tape 16 (1) and the succeeding tape 16 (2) shown in FIG. 14 (a) are in a conveying state before the power is cut off, and the sensor S1 on the downstream side in FIG. 14 (b) after the power is turned on again. As shown, when it turns off and does not match before and after power-off, it is determined that the preceding tape 16 (1) has dropped from the outlet 8e. Then, the component ID 63 (1) of the preceding tape 16 (1) in the feeder information 41a is updated with the component ID 63 (2) of the subsequent tape 16 (2), and the replacement flag 41c is updated to OFF (ST33).

  That is, the operation determination unit 21b determines that the component ID 63 that is the component information of the feeder information 41a stored in the feeder storage unit 41 (storage unit) and the replacement flag 41c (flag) are updated as the recovery processing operation. At this time, the corresponding component ID 63 in the component arrangement data 52b of the component mounting apparatuses M2 to M4 is also updated, and then the component supply operation is resumed. As a result, the state of the tape feeder 8 is automatically updated and the supply of parts can be resumed without the operator's judgment and operation.

  When the replacement flag 41c is off (No) in the flag confirmation step (ST32), the operation determination unit 21b determines whether or not the carrier tape 16 is newly inserted into the tape feeder 8 (ST34: insertion determination step). At this time, the operation determination unit 21b (determination unit) re-turns on the power and the presence / absence of the carrier tape 16 detected by the sensors S1, S2, and S3 (detection unit) stored when the power is shut off. Based on the presence or absence of the carrier tape 16 detected by the sensors S1, S2, and S3, it is determined whether or not the carrier tape 16 is newly inserted after the power is turned off.

  Here, since the tape feeder 8 includes the shutter mechanism 30 described above, the carrier tape 16 cannot be newly inserted if the shutter mechanism 30 is in the closed state. However, it is determined whether or not a new carrier tape 16 has been inserted on the assumption that the carrier tape has been forcibly inserted by the operator or the shutter mechanism 30 has not been opened or closed due to some influence.

  For example, as shown in FIG. 15 (a), the preceding tape 16 (1) exists including the detection position P1 and the detection position P2 before the power is shut off, and after the power is turned on again, the state shown in FIG. As shown, when the succeeding tape 16 (2) is inserted and detected at the detection position P3, the operation determining unit 21b determines that the carrier tape 16 is newly inserted from the insertion port 8d. That is, when the number of sensors for detecting the presence of the carrier tape 16 is increased after the power is turned back on (three, S1, S2, and S3) compared to before the power is shut off (two, S1 and S2), It is determined that the carrier tape 16 is newly inserted.

  As shown in FIG. 16 (a), the preceding tape 16 (1) exists including the detection position P1 before the power is shut off, and after the power is turned on again, as shown in FIG. 16 (b). When the tape 16 (1) falls out of the discharge port 8e and is not detected at the detection position P1, and the subsequent tape 16 (2) inserted from the insertion port 8d is detected at the detection position P2, the operation determination unit 21b. Determines that a new carrier tape 16 has been inserted. That is, only the downstream sensor S1 detects the presence of the carrier tape 16 before the power is turned off, and only the upstream sensor S2 detects the presence of the carrier tape 16 after the power is turned on again. It is determined that it has been inserted.

  As described above, when it is determined that the carrier tape 16 is newly inserted in the insertion determination step (ST34) (Yes), it is determined that an abnormality has occurred in the tape feeder 8, and an error is notified (ST35). That is, the operation determination unit 21b determines to notify the tape feeder 8 that an abnormality has occurred as a recovery processing operation. As a result, the operator can easily know that some change has occurred in the tape feeder 8 while the power is cut off and an abnormality has occurred.

  Note that the recovery processing operation for notifying that an abnormality has occurred in the tape feeder 8 may be a more detailed recovery processing operation depending on the state of the sensors S1 to S3 before power-off and after power-on again. For example, when the sensor S3 is turned on after the power is turned on again after the power is turned off before the power is shut off, it is determined that a new carrier tape has been inserted and the worker is notified as a recovery processing operation. You may decide.

  Next, the shutter mechanism 30 is maintained in the closed state (ST36). That is, the operation determination unit 21b determines to maintain the shutter mechanism 30 (shutter unit) in the closed state as the recovery processing operation. Thus, it is possible to prevent the carrier tape 16 from being erroneously inserted from the insertion port 8d before the recovery operation by the operator.

  When it is determined that the carrier tape 16 is not newly inserted in the insertion determining step (ST34) (No), it is determined that the preceding tape 16 (1) has dropped from the discharge port 8e as shown in FIG. Then, the operation / display panel 40 is notified that the carrier tape 16 has dropped (ST37). That is, the operation determining unit 21b determines to notify that the carrier tape 16 has dropped out as the recovery processing operation. Thus, the operator can easily know that the carrier tape 16 is accidentally dropped from the tape feeder 8 while the power is shut down and a recovery operation such as mounting of a new carrier tape 16 is necessary.

  Next, the component ID 63 (1) of the preceding tape 16 (1) is deleted from the feeder information 41a (ST38). That is, the operation determination unit 21b determines that the component ID 63, which is the component information of the feeder information 41a stored in the feeder storage unit 41 (storage unit), is updated as the recovery processing operation. Then, the corresponding component ID 63 (1) in the component arrangement data 52b of the component mounting apparatuses M2 to M4 is also deleted. Next, the process proceeds to (ST36), and the shutter mechanism 30 is maintained in the closed state. Thus, it is possible to prevent the carrier tape 16 from being erroneously inserted from the insertion port 8d before the recovery operation by the operator.

  The notification that the carrier tape 16 is newly inserted in (ST35) or the notification that the carrier tape 16 is accidentally dropped in (ST37) is notified to the display unit 18 of the component mounting apparatuses M2 to M4. May be. By doing so, the worker away from the tape feeder 8 can also know that there is a tape feeder 8 that requires a recovery operation by the worker.

  As described above, the tape feeder 8 (component supply device) of the present embodiment includes the sensor S1 and the sensor provided in the tape transport path 8c (transport path) for guiding the carrier tape 16 from the insertion port 8d to the discharge port 8e. The presence / absence of the carrier tape 16 is detected by S3 and the sensor S3 (detection unit), and an exchange flag 41c (flag) for designating the transport mode is designated based on the detected change in the presence / absence of the carrier tape 16. Then, the presence / absence of the detected carrier tape, the designated replacement flag 41c, and the component ID 63 (component information) stored in the carrier tape 16 mounted on the tape feeder 8 are stored in the feeder storage unit 41.

  Based on the detected presence / absence of the carrier tape 16 and the designated replacement flag 41c, the recovery processing operation when the power supplied to the tape feeder 8 is turned on again is determined. As a result, even if the carrier tape 16 is dropped from the tape feeder 8 while the power is cut off or a new carrier tape 16 is inserted, the recovery processing operation according to the situation can be determined. It is possible to prevent the wrong parts from being supplied without being noticed.

  The component supply device and the component supply method of the present invention have the effect that it is possible to prevent erroneous supply of components due to the carrier tape being detached from the tape feeder while the power is shut off, and are arranged in the component supply unit. This is useful in the field of mounting components in which components taken out from the tape feeder are transferred and mounted on a substrate.

8 Tape feeder (part supply device)
8a Body 8c Tape transport path (transport path)
8d Insertion port 8e Discharge port 16 Carrier tape 21a Mode designation part (designation part)
21b Operation determination unit (determination unit, determination unit)
23A First tape feeding mechanism (carrier tape transport mechanism)
23B Second tape feed mechanism (carrier tape transport mechanism)
29a Component pick-up position 30 Shutter mechanism (shutter part)
32a Shutter (Gate)
40 Operation / display panel (notification unit)
41 Feeder storage unit (storage unit)
41c Replacement flag (flag)
63 Component ID (component information)
M2 to M4 component mounting apparatus S1 first sensor (detection unit)
S2 Second sensor (detection unit)
S3 Third sensor (detection unit)

Claims (14)

A component supply device that supplies a component mounting device to a component mounting device by transporting a carrier tape covered with a cover tape and storing the component to a component removal position.
A main body provided with a conveyance path for guiding the carrier tape from the insertion port for inserting the carrier tape to the discharge port for discharging the carrier tape;
A carrier tape transport unit that transports the carrier tape and transports the stored components to a component removal position;
A detection unit for detecting the presence or absence of a carrier tape in the conveyance path;
Based on the change in the presence or absence of the detected carrier tape, a designation unit that designates the carrier mode of the carrier tape by a flag;
A storage unit for storing presence / absence of the detected carrier tape, the designated flag, and information of a component stored in the carrier tape mounted on the component supply device;
A component supply device comprising: a determination unit that determines a processing operation when power supplied to the component supply device is turned on again based on the presence or absence of the detected carrier tape and the designated flag.   The determination unit determines whether the presence / absence of the carrier tape stored when the power is turned off matches the presence / absence of the carrier tape detected when the power is turned on again, and when the power is turned off. The component supply apparatus according to claim 1, wherein the processing operation is determined based on a stored flag.   If the presence / absence of the carrier tape stored when the power is turned off matches the presence / absence of the carrier tape detected when the power is turned on again, the determination unit restarts the component supply operation. The component supply device according to claim 1, wherein the component supply device is determined as:   The determination unit does not match the presence / absence of the carrier tape stored when the power is turned off and the presence / absence of the carrier tape detected when the power is turned on again, and the stored flag indicates a plurality of carriers. 4. The component supply apparatus according to claim 1, wherein when the tape indicates that the tape is being conveyed, the processing operation is determined to update the information on the component and the flag. 5. Based on the presence or absence of the carrier tape stored when the power is turned off and the presence or absence of the carrier tape detected when the power is turned on again, it is determined whether or not a new carrier tape is inserted after the power is turned off. A determination unit;
A notification section for notifying that a new carrier tape has been inserted;
The determination unit does not match the presence / absence of the stored carrier tape and the presence / absence of the detected carrier tape, and the stored flag indicates that a plurality of carrier tapes are not in a transport state, 5. The component supply device according to claim 1, wherein when the determination unit determines that a new carrier tape is inserted, the processing operation is determined to notify that a new carrier tape has been inserted. . Based on the presence or absence of the carrier tape stored when the power is turned off and the presence or absence of the carrier tape detected when the power is turned on again, it is determined whether or not a new carrier tape is inserted after the power is turned off. A determination unit;
The determination unit does not match the presence / absence of the stored carrier tape and the presence / absence of the detected carrier tape, and the stored flag indicates that a plurality of carrier tapes are not in a transport state, The component supply device according to claim 1, wherein when the determination unit determines that a new carrier tape has not been inserted, the information processing unit determines to update the component information as the processing operation. Further comprising a shutter unit that is driven in an opening and closing direction, has a gate that suppresses insertion of the carrier tape into the insertion port in a closed state, and allows the carrier tape in an open state;
The determination unit maintains the shutter unit in a closed state when the presence or absence of the carrier tape stored when the power is turned off does not match the presence or absence of the carrier tape detected when the power is turned on again. The component supply apparatus according to claim 1, wherein this is determined as the processing operation. In a component supply device that supplies a component mounting device to the component mounting device by transporting a carrier tape that contains the component and covered with a cover tape to a component removal position.
The component supply device includes:
A main body provided with a conveyance path for guiding the carrier tape from the insertion port for inserting the carrier tape to the discharge port for discharging the carrier tape;
A carrier tape transport unit that transports the carrier tape and transports the stored components to a component removal position;
A detection unit for detecting the presence or absence of a carrier tape in the transport path,
Detecting the presence or absence of carrier tape in the conveying path;
Based on the change in presence or absence of the detected carrier tape, the carrier tape transport mode is designated by a flag,
Storing the information on the presence or absence of the detected carrier tape, the designated flag, and the component stored in the carrier tape mounted on the component supply device;
A component supply method for determining a processing operation when the power supplied to the component supply device is turned on again based on the presence / absence of the detected carrier tape and the designated flag.   The processing based on whether the presence or absence of the carrier tape stored when the power is turned off matches the presence or absence of the carrier tape detected when the power is turned on again, and the stored flag The component supply method according to claim 8, wherein the operation is determined.   When the presence / absence of the carrier tape stored when the power is shut off matches the presence / absence of the carrier tape detected when the power is turned on again, the restart of the component supply operation is determined as the processing operation. Item 10. The component supply method according to Item 8 or 9.   The presence or absence of the carrier tape stored when the power is shut off does not match the presence or absence of the carrier tape detected when the power is turned on again, and the stored flag indicates that a plurality of carrier tapes are being conveyed. 11. The component supply method according to claim 8, wherein when the information indicates that the information of the component and the flag are updated, it is determined as the processing operation.   The presence or absence of the carrier tape stored when the power is shut off does not match the presence or absence of the carrier tape detected when the power is turned on again, and the stored flag indicates that a plurality of carrier tapes are being conveyed. If it is determined that a new carrier tape has been inserted after power-off based on the presence or absence of the stored carrier tape and the presence or absence of the detected carrier tape, a new carrier tape The component supply method according to claim 8, wherein notifying that it has been inserted is determined as the processing operation.   The presence or absence of the carrier tape stored when the power is shut off does not match the presence or absence of the carrier tape detected when the power is turned on again, and the stored flag indicates that a plurality of carrier tapes are being conveyed. If it is determined that a new carrier tape has not been inserted after power-off based on the presence or absence of the stored carrier tape and the presence or absence of the detected carrier tape, information on the part The component supply method according to claim 8, wherein the processing operation is determined to be updated. The component supply device further includes a shutter unit having a gate that is driven in an opening / closing direction, and has a gate that suppresses insertion of the carrier tape into the insertion port in a closed state and allows the carrier tape in an open state.
If the presence or absence of the carrier tape stored when the power is turned off does not match the presence or absence of the carrier tape detected when the power is turned on again, the processing operation is performed to maintain the shutter unit in a closed state. The component supply method according to claim 8, wherein the component supply method is determined as follows.

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