JP7356274B2 - Parts management system and parts management method - Google Patents

Description

The present invention relates to a parts management system and a parts management method.

In the manufacturing process of electronic devices, a parts management system as disclosed in Patent Document 1 is used.

JP2019-091771A

Parts delivered from parts suppliers are stored in an automated warehouse. Components used in the mounting device are transported to the component mounting device after being taken out of the automated warehouse. In order to suppress a decline in the manufacturing efficiency of electronic devices, it is necessary to efficiently ship appropriate parts.

Aspects of the present invention aim to efficiently dispatch appropriate parts.

According to an aspect of the present invention, there is provided a serving table file acquisition unit that acquires a serving table file indicating parts to be assigned to each of a plurality of mounting devices, and a shipping command that outputs a shipping command for parts based on the serving table file. A parts management system is provided, comprising a section.

According to the aspect of the present invention, appropriate parts can be efficiently delivered.

FIG. 1 is a perspective view schematically showing a production system according to this embodiment. FIG. 2 is a configuration diagram showing the production system according to this embodiment. FIG. 3 is a perspective view showing parts according to this embodiment. FIG. 4 is a plan view schematically showing the mounting apparatus according to this embodiment. FIG. 5 is a perspective view showing the automated warehouse and elevator system according to this embodiment. FIG. 6 is a rear view showing the automated warehouse according to this embodiment. FIG. 7 is a sectional view showing the elevator apparatus according to this embodiment. FIG. 8 is a diagram schematically showing a part of the elevator apparatus according to this embodiment. FIG. 9 is a perspective view showing the component transport device according to this embodiment. FIG. 10 is a functional block diagram showing the warehouse control device according to this embodiment. FIG. 11 is a schematic diagram for explaining the serving table file according to this embodiment. FIG. 12 is a schematic diagram for explaining the work order according to this embodiment. FIG. 13 is a diagram schematically showing a display device of an information terminal according to this embodiment. FIG. 14 is a diagram schematically showing the individual identifier according to this embodiment. FIG. 15 is a diagram schematically showing component data according to this embodiment. FIG. 16 is a flowchart showing the warehousing process according to this embodiment. FIG. 17 is a flowchart showing the warehousing process according to this embodiment. FIG. 18 is a flowchart showing the confirmation process according to this embodiment. FIG. 19 is a flowchart showing the file shipping process according to this embodiment. FIG. 20 is a flowchart showing the selective exit process according to this embodiment. FIG. 21 is a flowchart showing out-of-parts retrieval processing according to this embodiment. FIG. 22 is a flowchart showing zero processing according to this embodiment. FIG. 23 is a flowchart showing the zero reset process according to this embodiment. FIG. 24 is a block diagram showing a computer system according to this embodiment.

Embodiments according to the present invention will be described below with reference to the drawings, but the present invention is not limited thereto. The components of the embodiments described below can be combined as appropriate. Furthermore, some components may not be used.

In the embodiment, an XYZ orthogonal coordinate system is set, and the positional relationship of each part will be explained with reference to the XYZ orthogonal coordinate system. The direction parallel to the X-axis in a predetermined plane is the X-axis direction, the direction parallel to the Y-axis in a predetermined plane perpendicular to the X-axis is the Y-axis direction, and the direction parallel to the Z-axis perpendicular to the X-axis and Y-axis Z-axis direction. In the embodiment, the predetermined plane is parallel to the horizontal plane, and the Z-axis direction is the vertical direction. Note that the predetermined surface may be inclined with respect to the horizontal surface. Furthermore, in the following description, the predetermined plane will be appropriately referred to as an XY plane.

[Production system]
FIG. 1 is a perspective view schematically showing a production system 1 according to this embodiment. FIG. 2 is a configuration diagram showing the production system 1 according to this embodiment. The production system 1 is installed in a factory facility. As shown in FIGS. 1 and 2, the production system 1 includes a component management system 2 that manages components C, a component mounting system 3 that manufactures electronic devices using the components C, a component management system 2, and a component mounting system 2 that manages components C. It includes a management control device 4 that controls the system 3 and an information terminal 5 that is operated by a worker WM.

The parts management system 2 includes an automatic warehouse 6, an elevator device 7, a warehouse control device 8, a parts transport device 9, and a transport control device 10. The component mounting system 3 includes a mounting device 11 and a production control device 12.

The automatic warehouse 6 stores parts C. The elevator device 7 takes parts C into and out of the warehouse. Stocking the parts C means transporting the parts C into the automated warehouse 6. Taking out the parts C means taking out the parts C from the automated warehouse 6. The elevator device 7 transports the parts C in the vertical direction in order to store the parts C and take them out of the warehouse. The warehouse control device 8 outputs control commands to control the automated warehouse 6 and the elevator device 7.

The component transport device 9 transports the component C. The parts transport device 9 travels on a travel path 13 defined on the floor of the factory facility. A plurality of component transport devices 9 are operated in the factory facility. The transport control device 10 outputs a control command to control the component transport device 9. The transport control device 10 communicates wirelessly with the component transport device 9.

The mounting device 11 mounts the component C onto the board P. The production control device 12 outputs control commands to control the mounting device 11.

The management control device 4 communicates with each of the warehouse control device 8, the transport control device 10, and the production control device 12. Each of the warehouse control device 8, the transport control device 10, and the production control device 12 operates based on a management command output from the management control device 4.

In the factory facility, an in/out space 14, a parts supply space 15, a receiving space 16, a setup space 17, and a charging space 18 are defined. The parts transport device 9 is movable to each of the loading/unloading space 14, the parts supply space 15, the receiving space 16, the setup space 17, and the charging space 18.

The loading/unloading space 14 is used for the process of passing the parts C stored in the automated warehouse 6 from the parts transport device 9 to the elevator device 7, and the process of passing the parts C taken out from the automated warehouse 6 from the elevator device 7 to the parts transport device 9. This is the space where this is carried out. The entry/exit space 14 is defined by the elevator device 7 .

The component supply space 15 is a space where the process of installing the component C on the tape feeder 117 of the mounting apparatus 11 is performed. The component supply space 15 is defined near the mounting device 11 . The worker WM present in the component supply space 15 installs the component C on the tape feeder 117 of the mounting apparatus 11 .

The receiving space 16 is a space where a process for receiving parts C delivered from a parts supplier is performed. A workbench 19 is installed in the receiving space 16. Part C is delivered from a parts supplier to a factory facility by means of a transport vehicle. The worker WM existing in the receiving space 16 receives the delivered part C.

The setup space 17 is a space where a process of loading a plurality of parts C onto the batch exchange cart 20 is performed. A batch exchange cart 20 is arranged in the setup space 17. The worker WM present in the setup space 17 loads the plurality of parts C onto the batch exchange cart 20.

The charging space 18 is a space where a process for charging the battery of the component transport device 9 is performed. A charging device 21 is installed in the charging space 18. When the amount of charge of the battery decreases, the component transport device 9 moves to the charging space 18 and charges the battery with the charging device 21.

The information terminal 5 is owned by the worker WM. The information terminal 5 includes a smartphone or a tablet personal computer. The information terminal 5 wirelessly communicates with the warehouse control device 8 .

[parts]
FIG. 3 is a perspective view showing the component C according to this embodiment. As shown in FIG. 3, the component C is held on the carrier tape 22. The carrier tape 22 holds a plurality of components C. The carrier tape 22 is wound onto a tape reel 23. The carrier tape 22 and tape reel 23 function as a holding member that holds the component C.

The carrier tape 22 is delivered from a parts supplier in a state wound around a tape reel 23 . The carrier tape 22 is handled while being wound around a tape reel 23.

A plurality of parts C held on tape reels 23 are stored in the automatic warehouse 6, stored in the automatic warehouse 6, taken out from the automatic warehouse 6, transported by the elevator device 7, or transported by the parts transport device. 9.

In this embodiment, warehousing the parts C includes warehousing the tape reel 23 into the automated warehouse 6. Storage of the parts C includes storing the tape reel 23 in the automated warehouse 6. Taking out the parts C includes taking out the tape reel 23 from the automated warehouse 6. Transporting the component C includes transporting the tape reel 23 by the elevator device 7 and transporting the tape reel 23 by the component transport device 9.

An individual identifier 24 for identifying the component C is given to the tape reel 23. The tape reel 23 is delivered from a parts supplier with an individual identifier 24 attached thereto.

The individual identifier 24 is provided on the surface of the tape reel 23. The component C held on the tape reel 23 is identified by the individual identifier 24. In this embodiment, the individual identifier 24 includes a barcode. The barcode may be a one-dimensional barcode or a two-dimensional barcode. Note that the individual identifier 24 may be at least one of numbers, letters, and graphics. Note that the individual identifier 24 may be at least one of an RFID tag (Radio Frequency Identifier Tag) and an RFID seal (Radio Frequency Identifier Seal).

In this embodiment, giving the individual identifier 24 to the tape reel 23 means giving the individual identifier 24 to the component C. The individual identifier 24 is given to each of the plurality of tape reels 23. Giving the individual identifier 24 to each of the plurality of tape reels 23 means giving the individual identifier 24 to each of the plurality of parts C.

In the parts management system 2, the parts C are handled while being supported by a tray 30. A plurality of empty trays 30 are arranged in the receiving space 16. The worker WM in the receiving space 16 sets the delivered tape reel 23 on the tray 30 on the workbench 19.

The tape reel 23 is supported by the tray 30 and is stored in the automated warehouse 6 , stored in the automated warehouse 6 , taken out from the automated warehouse 6 , transported by the elevator device 7 , or transported by the parts transport device 9 . Transported by.

In this embodiment, warehousing the tape reel 23 includes warehousing the tray 30 that supports the tape reel 23 into the automated warehouse 6. Storing the tape reel 23 includes storing the tray 30 that supports the tape reel 23 in the automated warehouse 6. Taking out the tape reel 23 includes taking out the tray 30 that supports the tape reel 23 from the automated warehouse 6. Transporting the tape reel 23 includes transporting the tray 30 supporting the tape reel 23 by the elevator device 7 and transporting the tray 30 supporting the tape reel 23 by the component transport device 9.

The tray 30 includes a plate portion 31 and a spacer portion 32 provided in at least a portion of the peripheral area of the upper surface of the plate portion 31 . The tape reel 23 is installed on the upper surface of the plate section 31. The upper surface of the spacer portion 32 is a flat surface. In a state where the tape reel 23 is arranged on the upper surface of the plate section 31, the upper surface of the spacer section 32 is arranged substantially in the same plane as the surface of the tape reel 23 or at a higher position than the surface of the tape reel 23. Thereby, a plurality of trays 30 can be stacked with the tape reel 23 supported by the tray 30.

In the example shown in FIG. 3, two tape reels 23 are supported on the tray 30. Note that the number of tape reels 23 supported by the tray 30 may be one, or any number of three or more.

[Mounting equipment]
FIG. 4 is a plan view schematically showing the mounting apparatus 11 according to this embodiment. The mounting device 11 mounts the component C onto the board P. The mounting device 11 includes a substrate transport device 111 that transports the board P, a component supply device 112 that supplies the component C, a mounting head 114 having a nozzle 113, a head moving device 115 that moves the mounting head 114, and a nozzle 113. and a nozzle moving device 116 for moving the nozzle.

The board transport device 111 transports the board P to the mounting position DM. The mounting position DM is defined on the transport path of the substrate transport device 111.

The component supply device 112 supplies the component C to the supply position SM. Component supply device 112 includes a plurality of tape feeders 117. The tape reel 23 is attached to the tape feeder 117. Each of the plurality of tape reels 23 is attached to each of the plurality of tape feeders 117.

Nozzle 113 releasably holds component C. The nozzle 113 may be a suction nozzle that sucks and holds the component C, or may be a grip nozzle that holds the component C by sandwiching it therebetween.

The mounting head 114 holds the component C supplied from the component supply device 112 with a nozzle 113 and mounts it on the substrate P. The mounting head 114 is movable between a supply position SM where the component C is supplied from the component supply device 112 and a mounting position DM where the board P is placed. The mounting head 114 holds the component C supplied to the supply position SM with the nozzle 113, moves to the mounting position DM, and then mounts the component C on the substrate P placed at the mounting position DM.

The tape feeder 117 rotates the tape reel 23 and sequentially supplies the plurality of components C held on the carrier tape 22 to the supply position SM. The mounting head 114 sequentially mounts the plurality of components C held on the tape reel 23 onto the board P. That is, the mounting apparatus 11 sequentially consumes the plurality of components C on the tape reel 23. In this embodiment, consuming the component C on the tape reel 23 includes unloading the component C from the carrier tape 22 on the tape reel 23 . The mounting head 114 takes out the components C one by one from the tape reel 23 and mounts them onto the board P.

The head moving device 115 moves the mounting head 114. The head moving device 115 includes a first moving device 115X that moves the mounting head 114 in the X-axis direction and a second moving device 115Y that moves the mounting head 114 in the Y-axis direction.

The nozzle moving device 116 moves the nozzle 113 in each of the Z-axis direction and the rotation direction around the Z-axis. The nozzle moving device 116 is supported by the mounting head 114.

The nozzle 113 is movable in each of the X-axis direction, the Y-axis direction, the Z-axis direction, and the rotation direction about the Z-axis by the head moving device 115 and the nozzle moving device 116. As the nozzle 113 moves, the component C held by the nozzle 113 can also move in each of the X-axis direction, the Y-axis direction, the Z-axis direction, and the rotation direction around the Z-axis.

[Automated warehouse and elevator equipment]
FIG. 5 is a perspective view showing the automated warehouse 6 and elevator device 7 according to this embodiment. FIG. 6 is a rear view showing the automated warehouse 6 according to this embodiment.

The automatic warehouse 6 stores a plurality of tape reels 23. The elevator device 7 stores a plurality of tape reels 23 into the automated warehouse 6. An individual identifier 24 is given to each of the plurality of tape reels 23 before being stored in the automated warehouse 6.

The tape reel 23 is stored in the automated warehouse 6 while being supported by the tray 30. The elevator device 7 performs a warehousing process of warehousing the trays 30 into the automated warehouse 6 and a warehousing process of taking the trays 30 out of the automated warehouse 6.

As shown in FIGS. 5 and 6, an intermediate warehouse 40 is arranged between the automatic warehouse 6 and the elevator device 7. The trays 30 before being shipped are temporarily stored in an intermediate warehouse 40. The automatic warehouse 6 and the intermediate warehouse 40 are connected by a cover 41.

The intermediate warehouse 40 has an entrance/exit 42 through which trays pass, and a shutter 43 that opens/closes the entrance/exit 42 . The shutter 43 opens the entry/exit port 42 when the tray 30 is stored or taken out, and closes the entry/exit port 42 when the tray 30 is not stored or taken out. Thereby, temperature changes and humidity changes in the internal space of the intermediate warehouse 40 are suppressed.

FIG. 7 is a sectional view showing the elevator device 7 according to this embodiment. The elevator device 7 includes a frame 44, an elevating stage 45 that supports the tray 30 and is movable up and down, and an elevating mechanism 46 that moves the elevating stage 45 up and down. The elevating mechanism 46 includes a ball screw mechanism connected to at least a portion of the elevating stage 45 and a motor that drives the ball screw mechanism.

Further, the elevator device 7 includes a side guide member 47 that is provided on the elevating stage 45 and guides the side surface of the tray 30. The tray 30 is arranged inside the side guide member 47.

The trays 30 are stacked on a lifting stage 45. The component transport device 9 can transport a plurality of stacked trays 30. The plurality of trays 30 transported by the component transport device 9 are passed to the elevating stage 45 in a stacked state. Further, the plurality of trays 30 supported by the lifting stage 45 are delivered to the component transport device 9 in a stacked state.

When unloading the tray 30 from the automated warehouse 6, the warehouse control device 8 controls the lifting mechanism 46 so that the upper surface of the lifting stage 45 is placed at the same height as the loading/unloading port 42. The trays 30 existing in the intermediate warehouse 40 are taken out from the intermediate warehouse 40 by a transport mechanism (not shown) provided in the elevator device 7. The trays 30 that have been unloaded from the intermediate warehouse 40 pass through the loading/unloading port 42 and are unloaded from the intermediate warehouse 40 . The tray 30 taken out from the intermediate warehouse 40 is placed on a lifting stage 45. When the tray 30 is placed on the lift stage 45, the warehouse control device 8 controls the lift mechanism 46 so that the lift stage 45 is lowered by the same distance as the height of the tray 30. By repeating the unloading of the trays 30 and the lowering of the elevating stage 45, a plurality of trays 30 are stacked on the elevating stage 45.

When loading trays 30 into the automated warehouse 6 , the warehouse control device 8 controls the tray 30 so that the uppermost tray 30 among the plurality of trays 30 stacked on the lifting stage 45 is placed at the same height as the loading/unloading port 42 . Then, the lifting mechanism 46 is controlled. The tray 30 is stored in the intermediate warehouse 40 by a transport mechanism (not shown) provided in the elevator device 7 . The tray 30 passes through the warehouse entrance 42 and is stored in the intermediate warehouse 40 . When the tray 30 is stored in the intermediate warehouse 40, the warehouse control device 8 controls the elevating mechanism 46 so that the elevating stage 45 rises by the same distance as the height of the tray 30. By repeating the storage of the trays 30 and the raising of the elevating stage 45, a plurality of trays 30 are sequentially carried out from the elevating stage 45.

FIG. 8 is a diagram schematically showing a part of the elevator apparatus 7 according to this embodiment. As shown in FIG. 8, the elevator device 7 includes a reading device 33, a detection device 34, and a providing device 35.

The reading device 33 reads the individual identifier 24 of the tape reel 23 in the elevator device 7 . The reading device 33 includes a camera. When the individual identifier 24 includes a barcode, the reading device 33 includes a barcode reader. If the individual identifier 24 includes an RFID tag or an RFID sticker, the reading device 33 includes an RFID reader.

The detection device 34 detects the component C held on the tape reel 23 in the elevator device 7. Detection device 34 includes an X-ray reel parts counting device. The detection device 34 detects the component C held on the tape reel 23 using an X-ray inspection method. The detection device 34 can detect the number of parts C held on the tape reel 23. The detection device 34 can detect the dimensions of the component C held on the tape reel 23. The dimensions of the component C include a dimension in the X-axis direction, a dimension in the Y-axis direction, and a dimension in the Z-axis direction. The detection device 34 can identify the type of the component C held on the tape reel 23 by detecting the dimensions of the component C. Note that the detection device 34 can detect the shape of the component C held on the tape reel 23. By detecting not only the dimensions of the component C but also the shape of the component C, the type of the component C can be specified with higher accuracy.

The assigning device 35 assigns the unified identifier 25 to the tape reel 23 in the elevator device 7 . The format of unique identifier 24 may vary depending on the component supplier. The individual identifier 24 of the tape reel 23 delivered from the first parts supplier is created in the first format, and the individual identifier 24 of the tape reel 23 delivered from the second parts supplier is created in the first format. It may have been created in a second format that is different from the . In this embodiment, individual identifiers 24 in different formats are converted into unified identifiers 25 in a unified format. The assigning device 35 assigns the unified identifier 25 to the tape reel 23 . The assigning device 35 assigns the unified identifier 25 to the tape reel 23 in the elevator device 7 before the tape reel 23 is stored in the automated warehouse 6. A unified identifier 25 is given to each of the plurality of tape reels 23 stored in the automated warehouse 6.

In this embodiment, giving the uniform identifier 25 to the tape reel 23 means giving the uniform identifier 25 to the component C. The unified identifier 25 is given to each of the plurality of tape reels 23. Giving the unified identifier 25 to each of the plurality of tape reels 23 means giving the unified identifier 25 to each of the plurality of parts C.

The assigning device 35 has an output device 36 that outputs the unified identifier 25 and an arm 37 that attaches the unified identifier 25 to the tray 30. If uniform identifier 25 includes a barcode, output device 36 includes a barcode label printer. The arm 37 attaches the unified identifier 25 output from the output device 36 to the surface of the tape reel 23.

[Parts conveyance device]
FIG. 9 is a perspective view showing the component transport device 9 according to this embodiment. The component transport device 9 includes a transport machine 50 having drive wheels 52 and a transport cart 51 attached to the transport machine 50. The tray 30 is supported by a transport cart 51. The transport cart 51 is removably attached to the transport machine 50. The transport machine 50 is self-propelled with the transport cart 51 connected thereto.

The transport cart 51 includes a pair of side covers 53, a top cover 54 that connects the upper ends of the pair of side covers 53, and a driven wheel 55 provided at the bottom of the side covers 53. The conveyor 50 is arranged in a space formed by a pair of side covers 53 and a top cover 54.

The transport cart 51 is disposed above the top cover 54 and includes a transport stage 56 that supports a plurality of trays 30, a front guide member 57 that guides the front surface of the tray 30 supported by the transport stage 56, and a rear surface of the tray 30. It has a rear guide member 58 for guiding. The front guide member 57 includes a pair of sub-guide members 57A and an opening/closing door 57B connected to one of the sub-guide members 57A. By opening the opening/closing door 57B, the tray 30 passes between the pair of sub-guide members 57A, and is carried out from the conveyance stage 56 or carried into the conveyance stage 56.

The tray 30 can move between the elevating stage 45 and the transport stage 56 while being guided by the front guide member 57 and the rear guide member 58.

[Warehouse control device]
FIG. 10 is a functional block diagram showing the warehouse control device 8 according to this embodiment. The warehouse control device 8 controls the automatic warehouse 6 and the elevator device 7. The warehouse control device 8 communicates with each of the management control device 4, the information terminal 5, the production control device 12, the reading device 33, the giving device 35, the detection device 34, and the notification device 38.

The warehouse control device 8 includes a meal plan file acquisition section 61, a work order acquisition section 62, an out-of-parts data acquisition section 63, a warehousing command section 64, a warehousing command section 65, an inventory management section 66, and an inventory data output section. unit 67, count value acquisition unit 68, count unit 69, zero processing unit 70, discard command unit 71, format storage unit 72, identification data acquisition unit 73, unified identifier output unit 74, parts data It has a registration section 75, a determination section 76, and a notification section 77.

The serving table file acquisition unit 61 acquires a serving table file indicating the components C to be allocated to each of the plurality of mounting devices 11 from the management control device 4 .

FIG. 11 is a schematic diagram for explaining the serving table file according to this embodiment. The component mounting system 3 has a plurality of mounting apparatuses 11. The type (name) of the component C to be assigned to each of the plurality of mounting apparatuses 11 is described in the meal plan file. The meal plan file indicates the type of parts C to be transported from the automatic warehouse 6 to each of the plurality of mounting apparatuses 11. Note that the meal plan file may include not only the types of components C but also the number of components C allocated to each of the plurality of mounting apparatuses 11.

In this embodiment, the meal plan file indicates tape reels 23 allocated to each of the plurality of mounting apparatuses 11. A plurality of tape feeders 117 are provided in one mounting apparatus 11. The meal plan file indicates tape reels 23 assigned to each of the plurality of tape feeders 117.

The meal plan file is defined based on the specifications of the mounting device 11 or the component supply device 112. Note that the meal plan file may be determined based on the electronic device to be manufactured. The meal plan file is registered in the management control device 4 before manufacturing the electronic device. The serving table file acquisition unit 61 acquires the serving table file registered in the management control device 4.

The work order acquisition unit 62 acquires a work order indicating the product of the number of boards P on which the parts C are mounted and the number of parts C mounted on the boards P from the management control device 4.

FIG. 12 is a schematic diagram for explaining the work order according to this embodiment. In manufacturing electronic equipment, the substrate P is sequentially transported to a plurality of mounting apparatuses 11. Each of the plurality of mounting devices 11 mounts the component C on the transported board P. An electronic device is manufactured by mounting components C on a board P using a plurality of mounting devices 11. In the example shown in FIG. 12, the first mounting device 11 mounts the component C on the first region Pa of the board P, the second mounting device 11 mounts the component C on the second region Pb of the board P, The third mounting device 11 mounts the component C on the third region Pc of the board P, and the fourth mounting device 11 mounts the component C on the fourth region Pd of the board P.

The type and number of components C to be mounted on the board P are determined based on the electronic device to be manufactured. Furthermore, the number of boards P on which the components C are mounted is determined based on the number of electronic devices to be manufactured. The work order indicates a part C determined based on the number of electronic devices to be manufactured. The work order indicates the type and number of parts C to be transported from the automated warehouse 6 to each of the plurality of mounting apparatuses 11. The work order is determined based on the electronic device to be manufactured. The work order is registered in the management control device 4 before manufacturing the electronic device. The work order acquisition unit 62 acquires work orders registered in the management control device 4.

The out-of-parts data acquisition unit 63 obtains out-of-parts data from the information terminal 5 indicating that the part C on the tape reel 23 has been consumed. Each of the plurality of tape reels 23 is attached to each of the plurality of tape feeders 117. Further, in the mounting apparatus 11, the plurality of components C on the tape reel 23 are sequentially consumed. The operator WM of the mounting apparatus 11 can recognize whether all the components C held on the tape reel 23 have been consumed. For example, when all the parts C held on the tape reel 23 are consumed, the production control device 12 activates a warning device provided in the mounting device 11. The warning device may be a warning light or an audio output device. The worker WM can recognize that all the parts C held on the tape reel 23 have been consumed based on the warning device. Note that the worker WM may visually recognize that all the parts C held on the tape reel 23 have been consumed. When the worker WM recognizes that all the parts C held on the tape reel 23 have been consumed, the worker WM operates the information terminal 5 to display a part out message indicating that all the parts C on the tape reel 23 have been consumed. The data is sent to the warehouse control device 8. The out-of-parts data acquisition unit 63 acquires out-of-parts data transmitted from the information terminal 5.

The parts out-of-part data includes identification data of the tape reel 23 in which all parts C have been consumed. A uniform identifier 25 is given to the tape reel 23. When the unified identifier 25 includes a barcode and the information terminal 5 has the function of a barcode reader, the worker WM uses the information terminal 5 to read the unified identifier 25 given to the tape reel 23 in which the component C has been completely consumed. read. As a result, the tape reel 23 in which all of the parts C have been consumed and the parts C in which all of the parts C have been consumed are specified. Based on the parts out of stock data transmitted from the information terminal 5, the parts out of stock data acquisition unit 63 can identify the tape reel 23 in which all of the parts C have been consumed and the parts C in which all of the parts C have been consumed.

The warehousing command unit 64 outputs a warehousing command for the tape reel 23 to the automated warehouse 6 and the elevator device 7. The warehousing command unit 64 outputs a warehousing command for warehousing the tape reel 23 delivered from the parts supplier and assigned the unified identifier 25 into the automated warehouse 6 .

The delivery command unit 65 outputs a delivery command for the tape reel 23 to the automated warehouse 6 and the elevator device 7. The retrieval command unit 65 outputs a retrieval command for retrieving the tape reels 23 , which are assigned the unified identifier 25 and stored in the automated warehouse 6 , from the automated warehouse 6 .

The delivery command unit 65 outputs a delivery command for the tape reel 23 based on the meal plan file. When the tape reel 23 is delivered from the automated warehouse 6 based on the meal plan file, the parts C suitable for the mounting apparatus 11 are delivered. By taking out the parts C suitable for the mounting apparatus 11, the parts C suitable for manufacturing electronic devices can be taken out efficiently.

Further, the delivery command unit 65 outputs a delivery command based on the selection command between the serving table file and the work order. The selection command is output from the information terminal 5. The worker WM can select, for example, based on the manufacturing status of the electronic device, between shipping the component C based on the serving list file and shipping the component C based on the work order. The worker WM operates the information terminal 5 and sends a selection command to the warehouse control device 8 between the delivery of the parts C based on the serving table file and the delivery of the parts C based on the work order. The exit command unit 65 acquires the selection command transmitted from the information terminal 5. The delivery command unit 65 outputs a delivery command based on the selection command by the worker WM. Thereby, parts C suitable for manufacturing electronic devices are efficiently delivered based on the selection by the worker WM.

Furthermore, the delivery command unit 65 outputs a delivery command based on the parts out-of-stock data. When all of the parts C of a specific tape reel 23 among the tape reels 23 attached to each of the plurality of tape feeders 117 are consumed, the worker WM operates the information terminal 5 to Parts out-of-parts data indicating that all parts C on the reel 23 have been consumed is transmitted to the warehouse control device 8. The delivery command unit 65 acquires out-of-parts data transmitted from the information terminal 5. As described above, the parts out-of-stock data includes identification data that identifies the tape reel 23 in which all the parts C have been consumed and the parts C in which all the parts C have been consumed. The retrieval command unit 65 outputs a retrieval command so that a tape reel 23 holding a component C of the same type as the completely consumed component C held on a specific tape reel 23 is retracted.

The inventory management unit 66 manages the inventory of parts C stored in the automatic warehouse 6. The inventory management unit 66 acquires inventory data of parts C stored in the automatic warehouse 6. The inventory management unit 66 stores the acquired inventory data. The inventory data includes identification data of parts C stored in the automated warehouse 6. The identification data of the component C includes the identification data of the uniform identifier 25 given to the tape reel 23. The inventory data of parts C includes the type (name) and number of parts C stored in the automated warehouse 6. The type of component C includes the type of component C held on each of the plurality of tape reels 23. The number of parts C includes the number of parts C held on each of the plurality of tape reels 23.

The inventory data output unit 67 outputs, to the information terminal 5, inventory data of a component C of the same type as the component C on the tape reel 23 that has been completely consumed in the mounting apparatus 11, based on the component out-of-stock data. For example, all the parts C of a predetermined type held on tape reels 23 in the mounting apparatus 11 are consumed, and a plurality of tape reels 23 holding parts C of the same type as the predetermined type of parts C are stocked in the automatic warehouse 6. If so, the inventory data output unit 67 transmits inventory data to the information terminal 5 indicating that the tape reel 23 holding the predetermined type of component C and the same type of component C are stored in the automated warehouse 6.

The information terminal 5 causes the display device of the information terminal 5 to display inventory data. In this embodiment, the inventory data displayed on the display device of the information terminal 5 includes list data indicating the storage times of the plurality of tape reels 23.

FIG. 13 is a diagram schematically showing a display device of the information terminal 5 according to this embodiment. When a plurality of tape reels 23 holding parts C of the same type as the first part C of a predetermined type are stored in the automated warehouse 6, each of the plurality of tape reels 23 holding parts C of the same type is The inventory data shown is displayed on the display device of the information terminal 5. As shown in FIG. 13, the display device of the information terminal 5 displays the serial numbers of the tape reels 23 stocked in the automated warehouse 6 and the storage time point indicating the time when the tape reels 23 were stocked in the automated warehouse 6. A list of data will be displayed.

The worker WM can operate the information terminal 5 to select a tape reel 23 to be delivered from a plurality of tape reels 23 stocked in the automated warehouse 6. The worker WM operates the information terminal 5 to transmit request data to the warehouse control device 8 to have the selected tape reel 23 removed from the automated warehouse 6 . The worker WM can operate the information terminal 5 to transmit, for example, request data to the warehouse control device 8 requesting the retrieval of the tape reel 23 with the longest elapsed time from the time of storage.

The delivery command unit 65 outputs a delivery command to deliver the tape reel 23 holding the component C selected from the inventory data by the worker WM. Based on the request data transmitted from the information terminal 5, the retrieval command unit 65 outputs a retrieval command for retrieving, for example, the tape reel 23 with the longest elapsed time from the time of warehousing.

The count value acquisition unit 68 acquires the count value of the component C of the tape reel 23 output from the information terminal 5. The worker WM counts the number of components C held on the tape reel 23 in the mounting apparatus 11. The worker WM operates the information terminal 5 to transmit a count value indicating the number of parts C held on the tape reel 23 to the warehouse control device 8. The count value acquisition unit 68 acquires the count value of the component C of the tape reel 23 transmitted from the information terminal 5.

The counting unit 69 acquires the count value of the component C on the tape reel 23 output from the production control device 12 that controls the mounting device 11 . The production control device 12 counts the number of components C carried out from the tape reel 23 and mounted on the substrate P based on the operation of the nozzle 113 and the operation of the mounting head 114. The production control device 12 outputs a count value indicating the number of parts C held on the tape reel 23 to the counting section 69. The counting unit 69 acquires the count value of the component C on the tape reel 23 transmitted from the production control device 12. The inventory management section 66 stores the count value of the parts C on the tape reel 23 obtained by the counting section 69.

When the zero processing unit 70 determines that all the parts C on the tape reel 23 have been consumed based on the count value of the parts C on the tape reel 23 output from the information terminal 5 and acquired by the count value acquisition unit 68, the zero processing unit 70 A zero processing command for changing the count value of component C of tape reel 23 stored in management section 66 to zero is output.

The count value of the parts C on the tape reel 23 obtained by the counting section 69 may be different from the number of parts C actually held on the tape reel 23. As described above, the count value of the component C on the tape reel 23 obtained by the counting unit 69 is calculated based on the operation of the nozzle 113 and the operation of the mounting head 114. For example, due to some reason such as a mounting error of the component C by the mounting head 114, the counted value of the components C obtained by the counting section 69 and the number of components C actually held on the tape reel 23 may differ. If the count value of parts C acquired by the counting unit 69 is different from the number of parts C actually held on the tape reel 23, the inventory management unit 66 will store an incorrect count value.

Therefore, even if the count value of the component C of the tape reel 23 stored in the inventory management unit 66 is greater than or equal to 1, the zero processing unit 70 will When it is determined that all the parts C on the tape reel 23 have been consumed based on the counted value of the parts C on the tape reel 23, zero sets the counted value of the parts C on the tape reel 23 stored in the inventory management section 66 to zero. Output processing instructions. The count value of parts C transmitted from the information terminal 5 is the number of parts C actually counted by the worker WM, and is a correct value. The inventory management unit 66 corrects the count value of the component C on the tape reel 23 stored in the inventory management unit 66 based on the count value of the component C transmitted from the information terminal 5. can be memorized.

Furthermore, even if the count value of the component C of the tape reel 23 stored in the inventory management unit 66 is zero, the zero processing unit 70 uses the count value of the component C of the tape reel 23 output from the information terminal 5. Based on this, when it is determined that the component C remains on the tape reel 23, it is possible to output a zero cancellation command to change the count value of the component C on the tape reel 23 stored in the inventory management section 66 to the remaining value. can.

The discard command unit 71 outputs a discard command for the tape reel 23 whose count value of the component C has become zero by the zero processing unit 70 to the inventory management unit 66 and the information terminal 5. The inventory management unit 66 erases the inventory data of the tape reel 23 in which the count value of the component C is zero based on the disposal command. The display device of the information terminal 5 displays display data for causing the worker WM to dispose of the tape reel 23 in which the count value of the component C is zero, based on the disposal command.

The format storage unit 72 stores the format of the individual identifier 24 given to each tape reel 23.

FIG. 14 is a diagram schematically showing the individual identifier 24 according to this embodiment. The identification data of the individual identifier 24 includes the type (name) of the component C held on the tape reel 23, the serial number of the component C, and the number of components C.

FIG. 14(A) shows the individual identifier 24 of the tape reel 23 delivered from the first parts supplier. FIG. 14(B) shows the individual identifier 24 of the tape reel 23 delivered from the second parts supplier. In the individual identifier 24 shown in FIG. 14(A), the first part 24A shows the type of part C, the second part 24B shows the serial number of part C, and the third part 24C shows the number of parts C. show. In the individual identifier 24 shown in FIG. 14(B), the fourth part 24D shows the serial number of the part C, the fifth part 24E shows the number of parts C, and the sixth part 24F shows the type of the part C. show.

As shown in FIGS. 14(A) and 14(B), the format of the individual identifier 24 of the tape reel 23 delivered from the first parts supplier and the format of the individual identifier 24 of the tape reel 23 delivered from the second parts supplier The format is different from that of the individual identifier 24.

The format storage unit 72 stores a plurality of formats of the individual identifier 24. The format storage unit 72 stores, for example, the format of the individual identifier 24 for each of a plurality of component suppliers.

The identification data acquisition unit 73 acquires from the reading device 33 the identification data of the individual identifier 24 read by the reading device 33 when the tape reel 23 is stored. The reading device 33 reads the individual identifier 24 by referring to the format of the individual identifier 24. Even if tape reels 23 having individual identifiers 24 in different formats are sequentially carried into the elevator device 7, the reading device 33 can read each of the plurality of individual identifiers 24 by referring to the format of the individual identifiers 24. .

The unified identifier output unit 74 outputs each of the plurality of tape reels 23 based on the format of the individual identifier 24 stored in the format storage unit 72 and the identification data of the individual identifier 24 acquired by the identification data acquisition unit 73. The identification data of the unified identifier 25 to be given to is generated. The unified identifier output unit 74 unifies the formats of the plurality of individual identifiers 24 based on the format of the individual identifiers 24 and the identification data of the individual identifiers 24, and generates the unified identifier 25 in the unified format. The unified identifier output unit 74 outputs the generated identification data of the unified identifier 25 to the assigning device 35.

In this embodiment, the identification data of the unified identifier 25 includes at least one of the type of component C held on the tape reel 23, the serial number of the component C, and the number of components C. The identification data of the unified identifier 25 may include only the type of component C, or may include only the serial number of component C. The identification data of the unified identifier 25 may include at least two of the type of component C, the serial number of component C, and the number of components C. In this embodiment, the identification data of the unified identifier 25 includes the type of component C and the serial number of component C, but does not include the number of components C. Since multiple formats are unified into one format, the component C held on the tape reel 23 can be identified based on the unified identifier 25 even if the amount of information included in the identification data is small.

The parts data registration unit 75 stores part data indicating the unique value of the parts C stored in the automated warehouse 6. The component data is registered in advance in the component data registration section 75 before the component C is stored in the automated warehouse 6.

FIG. 15 is a diagram schematically showing component data according to this embodiment. As shown in FIG. 15, in this embodiment, the component data includes the type (name) of the component C held on the tape reel 23, the number of components C, and the dimensions of the component C. The dimensions of the component C include a dimension in the X-axis direction, a dimension in the Y-axis direction, and a dimension in the Z-axis direction. Note that the component data may include the shape of the component C held on the tape reel 23.

The unified identifier output section 74 can output the identification data of the unified identifier 25 based on the detection data of the detection device 34 and the component data registered in the component data registration section 75. For example, there is a possibility that a tape reel 23 to which no individual identifier 24 is assigned may be delivered from a parts supplier. Even if the individual identifier 24 is not assigned to the tape reel 23 , the unified identifier output unit 74 assigns the tape reel 23 based on the detection data of the detection device 34 and the component data registered in the component data registration unit 75. It is possible to specify the component C held in the . The detection device 34 can detect the number of parts C and the dimensions of parts C. The component data registered in the component data registration section 75 includes the type (name) of the component C, the number of the components C, and the dimensions of the component C. Therefore, the unified identifier output section 74 identifies the type of component C held on the tape reel 23 by comparing the detection data of the detection device 34 and the component data registered in the component data registration section 75. can do. By specifying the type of component C held on the tape reel 23, the unified identifier output unit 74 can output the identification data of the unified identifier 25.

The determination unit 76 compares the detection data of the detection device 34, the component data registered in the component data registration unit 75, and the identification data of the unified identifier 25 given to the tape reel 23, and determines the unified identifier 25. Determine whether the is correct or not. For example, the unified identifier 25 that should be assigned to the first tape reel 23 may be assigned to the second tape reel 23 by mistake. After the unified identifier 25 is assigned to the tape reel 23 by the assigning device 35, when a confirmation process is performed to determine whether the unified identifier 25 assigned to the tape reel 23 is correct or not, the determining unit 76 detects the detection by the detecting device 34. By comparing the data, the component data registered in the component data registration section 75, and the identification data of the unified identifier 25 given to the tape reel 23, it is possible to determine whether the unified identifier 25 is correct or not.

The notification unit 77 outputs an operation command to the notification device 38 based on the determination data of the determination unit 76. The notification device 38 may be, for example, a warning light provided in the elevator device 7 or an audio output device. If the determining section 76 determines that the wrong unified identifier 25 has been assigned to the tape reel 23, the notifying section 77 outputs an operation command to the notifying device 38 based on the determination data of the determining section 76. By activating the notification device 38, the worker WM can recognize that the wrong unified identifier 25 has been given to the tape reel 23.

[Inbound processing (if there is an individual identifier)]
FIG. 16 is a flowchart showing the warehousing process according to this embodiment. FIG. 16 shows the warehousing process when the tape reel 23 is given the individual identifier 24. A tape reel 23 delivered from a parts supplier is carried into the elevator device 7 by a parts transport device 9. The reading device 33 reads the individual identifier 24 in the elevator device 7 . The identification data acquisition unit 73 acquires the identification data of the individual identifier 24 read by the reading device 33 (step SA1).

The identification data of the individual identifier 24 includes the type (name) of the part C held on the tape reel 23, the serial number of the part C held on the tape reel 23, and the part C held on the tape reel 23. Contains numbers. The type, serial number, and number of parts C acquired by the identification data acquisition unit 73 are stored in the inventory management unit 66 (step SA2).

The unified identifier output unit 74 outputs the identification data of the unified identifier 25 based on the format of the individual identifier 24 stored in the format storage unit 72 and the identification data of the individual identifier 24 acquired by the identification data acquisition unit 73. generate. The unified identifier output unit 74 outputs the generated identification data of the unified identifier 25 to the assigning device 35 (step SA3).

The unified identifier output unit 74 outputs an operation command for operating the assigning device 35. The assigning device 35 assigns a unified identifier 25 to the tape reel 23. After the unified identifier 25 is assigned to the tape reel 23, the warehousing command unit 64 outputs a warehousing command to cause the tape reel 23 to be warehoved into the automated warehouse 6 (step SA4).

The automated warehouse 6 stores a plurality of tape reels 23 to which a unified identifier 25 is assigned.

[Inbound processing (if there is no individual identifier)]
FIG. 17 is a flowchart showing the warehousing process according to this embodiment. FIG. 17 shows the warehousing process when the individual identifier 24 is not assigned to the tape reel 23. A tape reel 23 delivered from a parts supplier is carried into the elevator device 7 by a parts transport device 9. The detection device 34 detects the component C held on the tape reel 23 in the elevator device 7. The unified identifier output unit 74 acquires detection data from the detection device 34 (step SB1).

The unified identifier output section 74 registers the component C carried into the elevator device 7 in the component data registration section 75 based on the detection data of the detection device 34 and the component data registered in the component data registration section 75. It is determined whether or not the part C is the one shown in the figure (step SB2).

The detection data of the detection device 34 includes the dimensions and number of the parts C. The component data registered in the component data registration section 75 includes the dimensions and number of the component C. Therefore, the unified identifier output section 74 compares the detection data of the detection device 34 with the component data registered in the component data registration section 75, so that the component C carried into the elevator device 7 is registered in the component data registration section 75. It can be determined whether the part C is registered in the section 75 or not.

In step SB2, if it is determined that the component C carried into the elevator device 7 is the component C registered in the component data registration unit 75 (step SB2: Yes), the unified identifier output unit 74 outputs the unified identifier 25. identification data is generated and output to the assigning device 35 (step SB3).

The unified identifier output unit 74 outputs an operation command for operating the assigning device 35. The assigning device 35 assigns a unified identifier 25 to the tape reel 23. After the unified identifier 25 is assigned to the tape reel 23, the warehousing command unit 64 outputs a warehousing command to warehouse the tape reel 23 in the automated warehouse 6 (step SB4).

If it is determined in step SB2 that the component C carried into the elevator device 7 is not the component C registered in the component data registration section 75 (step SB2: No), the warehousing process ends. The tape reel 23 is carried out from the elevator device 7.

[Confirmation process]
FIG. 18 is a flowchart showing the confirmation process according to this embodiment. The confirmation process is a process of determining whether the unified identifier 25 given to the tape reel 23 is correct or not.

In the elevator device 7, the uniform identifier 25 is given to the tape reel 23 by the giving device 35. After the unified identifier 25 is given to the tape reel 23 and before the tape reel 23 is stored in the automated warehouse 6, the reading device 33 reads the unified identifier 25 in the elevator device 7. The determination unit 76 acquires the identification data of the unified identifier 25 read by the reading device 33 (step SC1).

Furthermore, before the tape reel 23 is stored in the automated warehouse 6, the detection device 34 detects the component C held on the tape reel 23 in the elevator device 7. The determination unit 76 acquires detection data from the detection device 34 (step SC2).

The determination unit 76 compares the detection data of the detection device 34, the component data registered in the component data registration unit 75, and the identification data of the unified identifier 25 (step SC3).

The determining unit 76 determines whether the unified identifier 25 is correct or not by comparing the detection data, component data, and identification data (step SC4).

The identification data of the individual identifier 24 before being converted into the unified identifier 25 includes the type of component C, the serial number of component C, and the number of components C. The identification data of the unified identifier 25 includes the type of component C and the serial number of component C. The detection data of the detection device 34 includes the number of parts C and the dimensions of parts C. The component data includes the type of component C, the serial number of component C, and the number of components C. The determination unit 76 can identify the type of component C held on the tape reel 23 by comparing the detection data of the detection device 34 and the component data. The determining unit 76 compares the type of the component C specified by comparing the detection data of the detection device 34 and the component data with the type of the component C included in the identification data of the unified identifier 25, and determines the type of component C that should be assigned. It can be determined whether the unified identifier 25 is correctly assigned to the tape reel 23.

If it is determined in step SC4 that the unified identifier 25 has been correctly assigned to the tape reel 23 (step SC4: Yes), the warehousing command unit 64 outputs a warehousing command to cause the tape reel 23 to be stored in the automated warehouse 6. (Step SC5).

If it is determined in step SC4 that the unified identifier 25 is not correctly assigned to the tape reel 23 (step SC4: No), the notification section 77 outputs an operation command to the notification device 38 (step SC6).

By activating the notification device 38, the worker WM can recognize that the wrong unified identifier 25 has been given to the tape reel 23.

[File issue processing]
FIG. 19 is a flowchart showing the file shipping process according to this embodiment. The file delivery process refers to a process in which the tape reel 23 is delivered from the automated warehouse 6 based on the meal plan file.

The serving table file acquisition unit 61 acquires the serving table file from the management control device 4 (step SD1).

The delivery command unit 65 outputs a delivery command based on the serving table file acquired by the serving table file acquisition unit 61 (step SD2).

[Selected issue processing]
FIG. 20 is a flowchart showing the selective exit process according to this embodiment. The selective delivery process refers to a process in which the tape reel 23 is delivered from the automated warehouse 6 based on a selection command between delivery based on the serving list file and delivery based on the work order.

The delivery command unit 65 acquires the selection command between the meal plan file and the work order transmitted from the information terminal 5 (step SE1).

The delivery command unit 65 determines whether a serving table file has been selected based on the selection command (step SE2).

If it is determined in step SE2 that the serving table file has been selected (step SE2: Yes), the serving table file acquisition unit 61 acquires the serving table file from the management control device 4 (step SE3).

The delivery command unit 65 outputs a delivery command based on the serving table file acquired by the serving table file acquisition unit 61 (step SE4).

If it is determined in step SE2 that the work order has been selected (step SE2: No), the work order acquisition unit 62 acquires the work order from the management control device 4 (step SE5).

The delivery command unit 65 outputs a delivery command based on the work order acquired by the work order acquisition unit 62 (step SE4).

[Out of parts processing]
FIG. 21 is a flowchart showing out-of-parts retrieval processing according to this embodiment. The parts-out storage process refers to a process in which the tape reel 23 is removed from the automated warehouse 6 when all the parts C on a specific tape reel 23 are consumed in the mounting apparatus 11 .

The out-of-part data acquisition unit 63 acquires out-of-part data indicating that the part C on the tape reel 23 has been consumed from the information terminal 5 (step SF1).

The inventory management unit 66 determines whether there is a tape reel 23 in stock that holds a component C of the same type as the component C of the tape reel 23 that has been completely consumed in the mounting apparatus 11 (step SF2).

In step SF2, if it is determined that a plurality of tape reels 23 holding the same type of component C are in stock (step SF2: Yes), the inventory data output unit 67 outputs the mounting device The inventory data of the parts C of the same type as the parts C of the tape reel 23 that were completely consumed in Step 11 is output to the information terminal 5 (step SF3).

As described with reference to FIG. 13, when the inventory data is output to the information terminal 5, the inventory data is displayed on the display device of the information terminal 5. The display device of the information terminal 5 displays, as inventory data, list data indicating the serial numbers of the tape reels 23 stocked in the automated warehouse 6 and the time of receipt indicating the time when the tape reels 23 were stocked in the automated warehouse 6. is displayed.

The worker WM operates the information terminal 5 to select the tape reel 23 to be delivered from the plurality of tape reels 23 stocked in the automated warehouse 6. The worker WM operates the information terminal 5 to transmit, for example, request data to the warehouse control device 8 requesting the retrieval of the tape reel 23 with the longest elapsed time from the time of storage.

The delivery command unit 65 acquires the request data transmitted from the information terminal 5 (step SF4).

Based on the request data transmitted from the information terminal 5, the retrieval command unit 65 outputs a retrieval command for retrieving, for example, the tape reel 23 with the longest elapsed time from the time of storage (step SF5).

By taking out the tape reel 23 with the longest elapsed time from the time of storage, it is suppressed that the old tape reel 23 continues to be stored in the automated warehouse 6.

[Zero processing]
FIG. 22 is a flowchart showing zero processing according to this embodiment. Zero processing refers to processing for changing the count value of the component C of the tape reel 23 stored in the inventory management section 66 to zero.

The counting unit 69 obtains the count value of the component C on the tape reel 23 output from the mounting apparatus 11 (step SG1).

The count of components C on the tape reel 23 output from the mounting apparatus 11 is registered in the inventory management section 66. The inventory management section 66 stores the count value of the component C on the tape reel 23 obtained by the counting section 69 (step SG2).

The count acquisition unit 68 acquires the count of the component C of the tape reel 23 output from the information terminal 5 (step SG3).

The zero processing section 70 determines whether all the components C on the tape reel 23 have been consumed based on the count value of the components C on the tape reel 23 acquired by the count value acquisition section 68 (step SG4).

In step SG4, if it is determined that all the parts C on the tape reel 23 have been consumed (step SG4: Yes), the zero processing unit 70 calculates the count value of the parts C on the tape reel 23 stored in the inventory management unit 66. A zero processing command to change to zero is output (step SG5).

The discard command unit 71 outputs a discard command for the tape reel 23 whose count value of the component C has become zero by the zero processing unit 70 to the inventory management unit 66 and the information terminal 5 (step SG6).

The inventory management unit 66 erases the inventory data of the tape reel 23 in which the count value of the component C is zero based on the disposal command. The display device of the information terminal 5 displays display data for causing the worker WM to dispose of the tape reel 23 in which the count value of the component C is zero, based on the disposal command.

In step SG4, if it is determined that all the parts C on the tape reel 23 are not consumed (step SG4: No), the zero processing command is not output from the zero processing unit 70, and the zero processing ends.

Even if the actual count value of part C is zero and the count value stored in the inventory management unit 66 is a value of 1 or more, the inventory management unit 66 can perform the correct count by performing zero processing. Can memorize numerical values.

[Zero cancellation processing]
FIG. 23 is a flowchart showing the zero reset process according to this embodiment. The zero reset process is a process of changing the counted value of the component C on the tape reel 23 stored in the inventory management section 66 to the actual remaining value.

The counting unit 69 obtains the count value of the component C on the tape reel 23 output from the mounting apparatus 11 (step SH1).

The count of components C on the tape reel 23 output from the mounting apparatus 11 is registered in the inventory management section 66. The inventory management section 66 stores the count value of the component C on the tape reel 23 obtained by the counting section 69 (step SH2).

The count acquisition unit 68 acquires the count of the component C of the tape reel 23 output from the information terminal 5 (step SH3).

The zero processing section 70 determines whether or not the component C remains on the tape reel 23 based on the count value of the component C on the tape reel 23 acquired by the count value acquisition section 68 (step SH4).

In step SH4, if it is determined that all the parts C on the tape reel 23 have been consumed (step SH4: Yes), the zero processing unit 70 calculates the count value of the parts C on the tape reel 23 stored in the inventory management unit 66. A zero cancellation command to change to the actual remaining value is output (step SH5).

The remaining value refers to the number of parts C remaining on the tape reel 23. The count value of the component C transmitted from the information terminal 5 indicates the actual remaining value. The remaining number of parts C transmitted from the information terminal 5 is the number of parts C actually counted by the worker WM, and is a correct value. The inventory management unit 66 corrects the count value of the component C on the tape reel 23 stored in the inventory management unit 66 based on the remaining value of the component C transmitted from the information terminal 5. can be memorized.

The disposal command unit 71 outputs a restoration command for the tape reel 23 whose count value of the component C has been changed to the remaining value by the zero processing unit 70 to the inventory management unit 66 and the information terminal 5 (step SH6).

The inventory management unit 66 restores the erased inventory data of the tape reel 23 based on the restoration command. Based on the restoration command, the display device of the information terminal 5 displays display data for restoring the tape reel 23 whose remaining value of the component C is 1 or more to the mounting apparatus 11.

If it is determined in step SH4 that there is no component C left on the tape reel 23 (step SH4: No), the zero reset command is not output from the zero processing unit 70, and the zero reset process ends.

Even if the actual count value (remaining value) of component C is a value of 1 or more and the count value stored in the inventory management unit 66 is zero, the inventory management unit 66 can store correct count values.

[Computer system]
FIG. 24 is a block diagram showing an example of the computer system 1000. Each of the management control device 4, warehouse control device 8, transport control device 10, production control device 12, and information terminal 5 described above includes a computer system 1000. The computer system 1000 includes a processor 1001 such as a CPU (Central Processing Unit), a main memory 1002 including a non-volatile memory such as a ROM (Read Only Memory) and a volatile memory such as a RAM (Random Access Memory), It has a storage 1003 and an interface 1004 including an input/output circuit. Each of the functions of the management control device 4, the warehouse control device 8, the transport control device 10, the production control device 12, and the information terminal 5 is stored in the storage 1003 as a computer program. The processor 1001 reads the computer program from the storage 1003, expands it into the main memory 1002, and executes the above-described processing according to the computer program. Note that the computer program may be distributed to the computer system 1000 via a network.

In accordance with the above-described embodiment, the computer program acquires a serving table file indicating the parts C to be assigned to each of the plurality of mounting apparatuses 11, and outputs a delivery command for the parts C based on the serving table file. , can be executed.

[effect]
As explained above, according to this embodiment, parts C are delivered from the automated warehouse 6 based on the meal plan file. Therefore, the parts management system 2 can efficiently deliver parts C suitable for manufacturing electronic devices.

The worker WM can select between shipping based on a meal plan file and shipping based on a work order. The parts management system 2 can efficiently dispatch appropriate parts C based on the selection of the worker WM.

The parts management system 2 can efficiently issue parts of the same type as the parts C consumed in the mounting apparatus 11 based on the parts out-of-stock data.

On the display device of the information terminal 5, inventory data of the component C of the same type as the component consumed in the mounting device 11 is displayed. The worker WM can select an appropriate part C from the inventory data displayed on the display device of the information terminal 5.

List data indicating the storage time of the tape reel 23 is displayed on the display device of the information terminal 5. By taking out the tape reel 23 with the longest elapsed time from the time of storage, it is suppressed that the old tape reel 23 continues to be stored in the automated warehouse 6.

The out-of-part data includes identification data of the tape reel 23 on which the part C is consumed. The parts management system 2 can efficiently issue parts of the same type as the parts C consumed in the mounting apparatus 11 based on the identification data.

Even though the actual number of parts C held on tape reel 23 is zero, when the number of parts C stored in inventory management section 66 is one or more, zero processing is executed. By executing the zero process, the inventory management unit 66 can store the correct number of parts C.

A discard command is output for the tape reel 23 that has been zero-processed. By outputting the disposal command, it is possible to prevent empty tape reels 23 from continuing to be stored in the automatic warehouse 6 or from continuing to uselessly handle empty tape reels 23.

When the number of parts C stored in the inventory management section 66 is zero even though the actual number of parts C held on the tape reel 23 is 1 or more, zero cancellation processing is executed. . By executing the zero reset process, the inventory management unit 66 can store the correct number of parts C.

The individual identifier 24 of the tape reel 23 is converted into a unified identifier 25. Thereby, when identifying a plurality of tape reels 23 delivered from each of a plurality of component suppliers, it is possible to identify them by a single identification process. Therefore, the occurrence of errors in the identification process is suppressed. Moreover, the identification process is simplified, and a decrease in manufacturing efficiency of electronic devices is suppressed.

1... Production system, 2... Parts management system, 3... Parts mounting system, 4... Management control device, 5... Information terminal, 6... Automatic warehouse, 7... Elevator device, 8... Warehouse control device, 9... Parts transport device, 10...Transfer control device, 11...Mounting device, 12...Production control device, 13...Traveling path, 14...Input/output space, 15...Parts supply space, 16...Accepting space, 17...Setup space, 18...Charging space, 19 ...Workbench, 20...Batch exchange trolley, 21...Charging device, 22...Carrier tape, 23...Tape reel, 24...Individual identifier, 24A...First part, 24B...Second part, 24C...Third part, 24D ...Fourth part, 24E...Fifth part, 24F...Sixth part, 25...Uniform identifier, 30...Tray, 31...Plate section, 32...Spacer section, 33...Reading device, 34...Detection device, 35...Applying device , 36... Output device, 37... Arm, 38... Notification device, 40... Intermediate warehouse, 41... Cover, 42... In/out port, 43... Shutter, 44... Frame, 45... Elevating stage, 46... Elevating mechanism, 47... Side guide member, 50... Conveyance machine, 51... Conveyance cart, 52... Drive wheel, 53... Side cover, 54... Top cover, 55... Driven wheel, 56... Conveyance stage, 57... Front guide member, 57A... Sub guide member , 57B... Opening/closing door, 58... Rear guide member, 61... Serving list file acquisition section, 62... Work order acquisition section, 63... Parts out of stock data acquisition section, 64... Warehousing command section, 65... Warehousing command section, 66... Stock Management section, 67... Inventory data output section, 68... Count value acquisition section, 69... Count section, 70... Zero processing section, 71... Disposal command section, 72... Format storage section, 73... Identification data acquisition section, 74... Unification Identifier output section, 75... Component data registration section, 76... Judgment section, 77... Notification section, 111... Board transfer device, 112... Component supply device, 113... Nozzle, 114... Mounting head, 115... Head moving device, 115X... First moving device, 115Y... Second moving device, 116... Nozzle moving device, 117... Tape feeder, C... Component, P... Substrate, Pa... First area, Pb... Second area, Pc... Third area, Pd ... Fourth area, DM... Mounting position, SM... Supply position.

Claims (10)

a meal plan file acquisition unit that acquires a meal plan file indicating parts allocated to each of the plurality of mounting devices;
a work order acquisition unit that acquires a work order indicating the product of the number of boards on which parts are mounted and the number of parts mounted on the boards;
a dispatch command unit that outputs a parts dispatch command based on a selection command between the meal plan file and the work order transmitted from an information terminal ;
Parts management system. The parts are delivered in a state in which a plurality of the parts are held by a holding member,
The mounting device sequentially consumes the plurality of parts of the holding member,
comprising a parts out-of-parts data acquisition unit that acquires out-of-parts data indicating that the parts of the holding member have been consumed;
The warehousing command unit outputs the warehousing command based on the out-of-parts data.
The parts management system according to claim 1 . The out-of-parts data acquisition unit obtains the out-of-parts data from an information terminal,
an inventory data output unit that outputs inventory data of parts of the same type as the consumed parts to the information terminal based on the parts out-of-stock data;
The dispatch command unit dispatches the parts selected from the inventory data.
The parts management system according to claim 2 . A plurality of the holding members holding the same type of parts are kept in stock,
The inventory data includes list data indicating the storage time of the plurality of holding members,
The parts management system according to claim 3 . The component outage data includes identification data of the holding member in which the component is consumed.
The parts management system according to any one of claims 2 to 4 . The parts are delivered in a state in which a plurality of the parts are held by a holding member,
The mounting device sequentially consumes the plurality of parts of the holding member,
a counting unit that obtains a count of the components of the holding member output from the mounting device;
When it is determined that the parts of the holding member are consumed based on the counted value of the parts of the holding member output from the information terminal, output a zero processing command to change the counted value of the parts of the holding member to zero. A zero processing section;
The parts management system according to claim 1 . comprising a discard command section that outputs a discard command for the holding member whose count value has been changed to zero;
The parts management system according to claim 6 . When the zero processing unit determines that there are parts remaining in the holding member based on the counted value of the parts in the holding member output from the information terminal, the zero processing unit converts the counted value of the parts in the holding member into a remaining value. Output to zero reset command to change to,
The parts management system according to claim 6 or claim 7 . A plurality of the holding members are stored,
An individual identifier is given to each of the plurality of holding members,
a format storage unit that stores the format of the individual identifier;
an identification data acquisition unit that acquires identification data of the individual identifier read when the holding member is stored;
a unified identifier output unit that outputs identification data of a unified identifier given to each of the plurality of holding members based on the format and the identification data;
The parts management system according to any one of claims 2 to 8 . Obtaining a meal plan file indicating parts allocated to each of the plurality of mounting devices;
Obtaining a work order indicating the product of the number of boards on which parts are mounted and the number of parts mounted on the boards;
outputting a parts delivery command based on a selection command between the meal plan file and the work order transmitted from an information terminal ;
Parts management method.

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