A system for presenting isolated components to an assembly line over a plurality of cycles includes a container configured to direct components towards a central axis. An elongated pedestal within the container has ribs which define an upper surface and a plurality of channels. The pedestal is reciprocally mounted to move along the central axis, and isolates components during each cycle. The isolated components are transferred to an assembly line. The number of isolated components of each cycle is measured and the value stored. A threshold value is calculated based on a number of stored values. A running average of the quantity of isolated components for a number of cycles can then be compared to the threshold to determine when to refill the component container.

A line for the continuous cycle production of decorated ceramic products includes a feeding machine, a pressing machine and a colouring machine. Further, the line includes a supervision system that includes a line server and, for each machine: (i) a local control panel, connected to the corresponding machine and configured to generate configuration data representing a machine setup; and (ii) a print server, connected to a corresponding local control panel to receive the configuration data of the corresponding machine and process it to generate a machine configuration document representing the machine configuration data formatted according to a predetermined protocol. The line server can be connected to all of the print servers of the line to receive the configuration documents of the machines of the line, and be configured to generate a configuration document of the line, representing the setup of the line in its entirety.

A system for presenting isolated components to an assembly line over a plurality of cycles includes a container configured to direct components towards a central axis. An elongated pedestal within the container has ribs which define an upper surface and a plurality of channels. The pedestal is reciprocally mounted to move along the central axis, and isolates components during each cycle. The isolated components are transferred to an assembly line. The number of isolated components of each cycle is measured and the value stored. A threshold value is calculated based on a number of stored values. A running average of the quantity of isolated components for a number of cycles can then be compared to the threshold to determine when to refill the component container.

A gantry robot system may include a gantry, a slide movably mounted on the gantry, an articulated arm mounted on the slide for performing a machining operation, a workpiece feeder for moving a workpiece relative to the gantry, the workpiece feeder having a first guide element mounted on and selectively positionable on the gantry, and a second guide element movably mounted on the gantry, the second guide element connected to and selectively positionable by the first guide element to engage workpieces of varying widths, and a computer control connected to actuate the slide, the articulated arm, and the workpiece feeder in a coordinated manner to perform a preselected machining operation on the workpiece.

A setup change work support method includes a feeder information acquisition step, a production information acquisition step, and a target feeder determination step. The feeder information acquisition step acquires information on the capability of a feeder that can be disposed in a component supply unit of an electronic component mounting device for mounting an electronic component on a workpiece and that supplies the electronic component. The production information acquisition step acquires information on the production of the workpiece. The target feeder determination step determines a target feeder that is disposed in the component supply unit and is used to produce a target type based on information on the capability of the feeder and information on the production of the workpiece.

Each of a plurality of tape feeders arranged in a component feed section includes a display part which displays setting information stored in a feeder storage part, an operation input part which displays the setting information in the display part and a modification process part which outputs a signal for modifying the setting information stored in a main body storage part and the feeder storage part in accordance with an input of a modification operation. The modification operation of the setting information can be carried out in a flexible form and with a good working property.

A feeder automatic distribution control device includes a feeder replenishment section that sequentially replenishes feeders for replenishment, which mounting modules are to be replenished with, a feeder recovery section that sequentially recovers feeders for recovery, which are to be recovered from the mounting modules, a transport lane that transports the feeders for replenishment and the feeders for recovery between each of the feeder replenishment section, the feeder recovery section and the mounting modules, and a control section that controls replenishment and recovery of the feeders for replenishment and the feeders for recovery that are transported in the transport lane, and the control section performs control so that the replenishment of the feeders for replenishment and the recovery of the feeders for recovery are concurrently performed in a sequential manner from mounting modules that are on either an upstream side or a downstream side of the component mounting line.

Systems and methods of monitoring a production level of a vibratory feeder configured to process a workpiece are described herein. The methods include operating a processor to: receive device data associated with the vibratory feeder during operation of the vibratory feeder, the device data comprising at least one input state of the vibratory feeder; receive production data associated with the vibratory feeder, the production data being representative of a production level of the vibratory feeder; determine, based on the device data and/or the production data, one or more faults corresponding to the vibratory feeder when the production level falls below a threshold production level; and determine, based on the one or more faults, a corrective action to return the production level to or above the threshold production level.