A feed unit for articles includes: a first feeding device; a second feeding device for individually picking up the articles from the first feeding device at a removal location at a predetermined time interval; and a synchronization device for receiving the articles from the first feeding device and to moving the articles into the removal location. A control system is also provided, to adjust the speed of the synchronization device in such a manner that each article reaches the removal location at the predetermined time interval in order to be picked up by the second feeding device.

A feed unit for articles includes: a first feeding device; a second feeding device for individually picking up the articles from the first feeding device at a removal location at a predetermined time interval; and a synchronization device for receiving the articles from the first feeding device and to moving the articles into the removal location. A control system is also provided, to adjust the speed of the synchronization device in such a manner that each article reaches the removal location at the predetermined time interval in order to be picked up by the second feeding device.

A vacuum cup damage detection system detects vacuum cup damage or absence in a robot singulator including a vacuum-based end effector with one or more vacuum cups. The system generally comprises a plate and a control subsystem. The plate provides a potential point of engagement for the one or more vacuum cups of the vacuum-based end effector when the robot singulator is moved to a predetermined position in which, if present, at least one of the one or more vacuum cups of the vacuum-based end effector is in contact with the plate. The control subsystem includes: one or more sensors configured to obtain readings indicative of the engagement of the one or more vacuum cups with the plate or lack thereof; and a controller configured to determine whether any one of the vacuum cups is damaged or missing based on the readings obtained by the one or more sensors.

A vacuum cup damage detection system detects vacuum cup damage or absence in a robot singulator including a vacuum-based end effector with one or more vacuum cups. The system generally comprises a plate and a control subsystem. The plate provides a potential point of engagement for the one or more vacuum cups of the vacuum-based end effector when the robot singulator is moved to a predetermined position in which, if present, at least one of the one or more vacuum cups of the vacuum-based end effector is in contact with the plate. The control subsystem includes: one or more sensors configured to obtain readings indicative of the engagement of the one or more vacuum cups with the plate or lack thereof; and a controller configured to determine whether any one of the vacuum cups is damaged or missing based on the readings obtained by the one or more sensors.

A transfer operation control unit changes, according to an operating state index indicating a level of an operating state of a plurality of transport vehicles (1) present on a travel path, a setting of a transfer operation such that a required transfer time (Tr) from start to completion of the transfer operation is increased as the level of the operating state is reduced, while maintaining at least one setting of a traveling speed of the transport vehicles (1).

A transfer operation control unit changes, according to an operating state index indicating a level of an operating state of a plurality of transport vehicles (1) present on a travel path, a setting of a transfer operation such that a required transfer time (Tr) from start to completion of the transfer operation is increased as the level of the operating state is reduced, while maintaining at least one setting of a traveling speed of the transport vehicles (1).

A method for forming aggregates of food pieces by arranging a plurality of food pieces such that the food pieces at least partially overlap one another is provided. The method automatically changes the number of food pieces forming each aggregate and a pitch at which the food pieces are arranged so as to limit the weights of the aggregates within a predetermined permissible range and to form each aggregate such that the total length of the aggregate is a preset length. The method also automatically changes the number of food pieces forming each aggregate and the pitch at which the food pieces are arranged according to the length of the food piece in the arrangement direction.

A method for forming aggregates of food pieces by arranging a plurality of food pieces such that the food pieces at least partially overlap one another is provided. The method automatically changes the number of food pieces forming each aggregate and a pitch at which the food pieces are arranged so as to limit the weights of the aggregates within a predetermined permissible range and to form each aggregate such that the total length of the aggregate is a preset length. The method also automatically changes the number of food pieces forming each aggregate and the pitch at which the food pieces are arranged according to the length of the food piece in the arrangement direction.

An embodiment includes a plurality of transport modules forming a transport path on which a carriage that transports a workpiece travels, and a control unit that controls a position of the carriage on the plurality of transport modules based on a drive instruction, and the control unit corrects the drive instruction during carriage motion that is based on the drive instruction and stops the carriage.

An embodiment includes a plurality of transport modules forming a transport path on which a carriage that transports a workpiece travels, and a control unit that controls a position of the carriage on the plurality of transport modules based on a drive instruction, and the control unit corrects the drive instruction during carriage motion that is based on the drive instruction and stops the carriage.