A warehouse system includes a component container warehouse configured to store multiple component containers that accommodate multiple components, a component supply unit warehouse configured to store multiple component supply units used when supplying the components accommodated in the component container to a component mounter, a component container loader configured to load the component container into the component supply unit, and a conveyance robot configured to move between the component container warehouse, the component supply unit warehouse, and the component container loader to convey the component container and the component supply unit to the component container loader.

A component mounting system includes a component mounter group, a storage, and a loader. The storage is provided on an upstream side or a downstream side of the component mounter group and has a storage area in which multiple component supply devices are arranged and supported detachably. The loader automatically takes out and/or attach the component supply devices from and/or to the component mounters and the storage. When an occupancy state of the component supply device supported by the storage area reaches a predetermined high occupancy state, the control section of the component mounting system outputs at least one of a recovery urging warning for prompting recovery of the component supply devices supported by the storage area and a replenishment prohibition warning for prohibiting replenishment of the component supply device used in a next production or later onto the storage area.

A substrate working machine including: a conveyance device configured to convey a substrate; a holding device configured to hold the substrate conveyed to a work position by the conveyance device; and a control device configured to control operation of the conveyance device, wherein the control device is configured to control the operation of the conveyance device such that the substrate is conveyed at a conveyance speed calculated based on a preset setting time and a conveyance distance of the substrate from the work position by the conveyance device or a conveyance distance of the substrate to the work position by the conveyance device.

A tape erroneous mounting detection system includes sensors provided to the plurality of tape feeders, a reader configured to read identification information from a recording part which is provided to a reel, and a memory part configured to store part verification information. The tape erroneous mounting detection system also includes a part verification part configured to determine whether or not the tape is mounted on the tape feeder at the set position, and to perform verification updating processing, and a tape erroneous mounting detection part configured to perform erroneous mounting detection processing where the tape erroneous mounting detection part identifies the tape feeder on which the tape is mounted based on the tape presence or absence information and the output from the sensor, and the tape erroneous mounting detection part detects that the tape mounted on the tape feeder is erroneously mounted.

A control system of a tape feeder that includes a reel on which is wound component supply tape, and a tape feeding device configured to draw out the component supply tape from the reel to a component pickup position, the control system including a sensor configured to detect information relating to a remaining amount of the tape on the reel; and a motor control section configured to change an operation parameter of a motor that is a drive source of the tape feeding device based on the tape remaining amount information detected by the sensor. Specifically, the motor control section changes the operation parameter of the motor so as to reduce the motor torque as the tape remaining amount on the reel decreases, based on the tape remaining amount information detected by the sensor.

The simulation device includes a simulation section and a calculation section. A simulation section is configured to simulate an operating status of a board work machine configured to perform predetermined board work on a board and produce a board product, and an operating status of an article moving device configured to supply an article needed for production of the board product to the board work machine based on a production plan of the board product. A calculation section is configured to calculate a production stop time of the board work machine caused by a wait time from when production of the board product by the board work machine is stopped to when the article is supplied by the article moving device based on a result of simulation by the simulation section.

There is provided a component mounter including: a plurality of transport lanes for transporting a board sorted by a board sorting device; a congestion index calculator for calculating a congestion index indicating a congestion degree of each of the plurality of transport lanes; a transport lane determiner for determining a transport lane for carrying in the board among the plurality of transport lanes based on the calculated congestion index; and an outputter for outputting a board request signal for requesting to carry the board into the transport lane determined by the transport lane determiner, to the board sorting device.

A component supply device, including a stage on which components are scattered; an imaging device configured to image components scattered on the stage; a storage device configured to store first identification information capable of identifying a first component which is a component scheduled to be supplied from the stage and second identification information capable of identifying a second component which is a component not scheduled to be supplied from the stage; and a determination device configured to determine whether the first component is present on the stage based on the first identification information and imaging data from the imaging device, and to determine whether the second component is present on the stage based on the second identification information and imaging data from the imaging device.

A production management device, such as a production management computer, determines a production sequence of plural types of substrates in order to produce the substrates consecutively on a product type-by-type basis by using a component mounter including component supply devices. The production management device includes a main control unit for determining a production sequence of substrates such that, where a time from start to completion of off-line setup of all the component supply devices to be used for a single product type of substrate is defined as an off-line setup time, a sum of the off-line setup times for two product types of substrates to be consecutively produced is balanced over an entire period of consecutive production.

A component supply device includes a plurality of kinds of tape feeders capable of mounting a first component storing tape by which supplying of components is performed precedingly, and a second component storing tape by which supplying of components is performed succeedingly; a component sensor configured to detect runout of the components in the first component storing tape; and a control unit configured to control a tape feeding operation. A specified discharge length by which the first component storing tape is discharged at the time of occurrence of the runout of the components is preliminarily set for each kind of the tape feeder. The control unit is configured to make the tape feeder perform a tape feeding operation for feeding the first component storing tape by the specified discharge length when the component sensor detects the runout of the components in the first component storing tape.