A mounting device comprises a substrate stage, a mounting head, an elevating unit, a recognition mechanism, and a control unit. The recognition mechanism acquires position information about a chip recognition mark and a substrate recognition mark using an imaging unit. The control unit calculates an amount of positional deviation between a chip component and a substrate from the position information about the chip recognition mark and the substrate recognition mark, and performs alignment by driving the mounting head and/or the substrate stage according to the amount of the positional deviation. The chip component and the substrate are brought closer with each other and the alignment is performed in a state in which the imaging unit simultaneously images the chip recognition mark and the substrate recognition mark within a depth of field, after which the chip component and the substrate are brought into close contact with each other.

A method in an automated Surface Mount Device (SMD) warehouse configured to store bins at predetermined positions within said automated Surface Mount Device (SMD) warehouse, the method comprising receiving a bin at a port of said automated Surface Mount Device (SMD) warehouse and scanning an identity tag attached to said bin to obtain a bin ID.

A method in an automated Surface Mount Device (SMD) warehouse configured to store bins at predetermined positions within said automated Surface Mount Device (SMD) warehouse, the method comprising receiving a bin at a port of said automated Surface Mount Device (SMD) warehouse and scanning an identity tag attached to said bin to obtain a bin ID.

The image data generation device includes a component information input section and an image data generation section. The component information input section is configured to input a mounting position and an outer shape of the electronic component for each of the multiple electronic components to be mounted in the mounting processing. The mounting position includes a position in a height direction orthogonal to a surface of the board. The image data generation section is configured to generate image data for displaying a state when each of the multiple electronic components to be mounted in the mounting processing is arranged at the mounting position of the electronic component based on the mounting position and the outer shape of the electronic component input by the component information input section.

There are provided a carrier tape supply unit that supplies a carrier tape storing components, and a carrier tape processing unit that pulls out the carrier tape from the carrier tape supply unit, forms the carrier tape into a roll shape, and stores the carrier tape in a case. Further, the carrier tape processing unit includes a roll body creating unit that includes a shaft member holding a tip end part of the carrier tape, and creates a roll-shaped roll body by rotating the shaft member to wind the carrier tape around the shaft member, and a shaft member extracting unit that extracts the shaft member from the roll body created by the roll body creating unit.

Component-mounting system includes multiple component mounting machines disposed along a board conveyance direction; feeder storage container for storing multiples of feeders, which are capable of being attached/detached to and from component mounting machines, in each stage among multiple stages; first feeder moving robot capable of exchanging feeder between the lowest stage among multiple stages of feeder storage container and component mounting machine; and second feeder moving robot capable of exchanging feeder between the lowest stage among multiple stages of feeder storage container and the other stages.

An apparatus for manufacturing a display device including: a photographing member configured to photograph a first alignment mark, a second alignment mark, a third alignment mark, and a fourth alignment mark, which are provided in a display panel; and a control member configured to set an imaginary reference point, taking into account the first alignment mark, the second alignment mark, the third alignment mark, and the fourth alignment mark, which are photographed by the photographing member. The control member sets a first position which is included in the imaginary reference point and at which a first imaginary straight line connecting the first alignment mark to the third alignment mark and a second imaginary straight line connecting the second alignment mark to the fourth alignment mark cross each other.

A holder management device includes a storage device to store a tray that accommodates a component holder and a work machine that performs work using the component holder, a placement section on which the tray is placed, a transfer device to transfer the component holder used in the work machine stored in the storage device in correlation with the tray to the tray placed on the placement section, and a display device to display information indicating a tray to be placed on the placement section together with information indicating a work machine stored in the storage device in correlation with the tray, and in a case where the storage device stores multiple types of trays and work machines in correlation with each other, to display information indicating the multiple types of trays together with information indicating the work machines stored in the storage device.

An automated replacement device moves in a right-left direction along a front surface of production line including multiple machines. The automated replacement device moves to a front side of an instructed machine among the multiple machines to perform an automated replacement operation on the machine. A periphery monitoring device monitors a safety area set in a periphery of the automated replacement device to stop an operation of the automated replacement device in an emergency manner when a person or an obstacle is detected in the safety area and alarm device sounds an alarm to notify that the automated replacement device is moving, in which the periphery monitoring device is switched such that a range of the safety area during the movement of the automated replacement device is smaller than a range of the safety area during the automated replacement operation.

A component mounter includes a state recognition section configured to recognize a supply state of a component in a supply area based on a feature amount including at least one of a shape and an angle of each of multiple feature portions in image data on which image processing has been executed. The state recognition section determines whether one or more candidate feature portions included in a search range belong to an identical component together with a reference feature portion based on one of feature amounts of the candidate feature portion and a positional relationship between the reference feature portion and the candidate feature portion.