This application describes fabric storage totes, as well as techniques for use of fabric totes in an infrastructure that uses mechanical systems to transport the fabric totes and/or access inventory items in the fabric totes. The fabric totes may include a fabric base and side walls, with a hardened material support structure. Additionally, the fabric totes may include two handles made of a substantially hard material. The fabric totes may be accessed and transported, manually and/or mechanically, via interaction with the handles.

The production line configuration change system includes: an error information storage unit that stores information of an error which occurs in equipment on a production line; a work information storage unit that stores work contents required for manufacturing a product; an equipment information storage unit that stores constraint information of a tool mountable on the equipment; a production line configuration information storage unit that, in order of manufacturing processes of the product, stores a work content, work assignment equipment, a tool mounted on the equipment, and a process tact time in each of the manufacturing processes; and a production line configuration calculation unit that is activated immediately after the error occurs, prepares a change plan of assigning a work assigned to the equipment in which the error occurs to the equipment before or after the process or another equipment of the identical process and calculates a provisional production line configuration.

A conveyor controller for being implemented into a conveyor system includes control circuitry and one or more network interfaces for coupling with other conveyor controllers. In one embodiment, the control circuitry configured for detecting whether another conveyor controller is connected and to determine which network interface is used in order to set the direction of the conveyor system. In another embodiment, the control circuitry is configured, to receive configuration data from a conveyor controller connected to a network interface, and to detect if another conveyor controller is and to transmit configuration message to another conveyor controller that includes additional configuration data associated with the conveyor controller. In still another embodiment, the control circuitry transmits configuration data to a replacement conveyor controller upon getting a request from the replacement conveyor controller that has been connected to a network interface.

A control system for mechanical equipment is provided with: a manual operation mechanism provided with a minimum required number of operation switches and a mechanical equipment identification signal transmission unit for transmitting a mechanical equipment identification signal that identifies mechanical equipment; an operation assistance terminal in which the mechanical equipment identification signal received from the transmission unit is used as a basis to display a manual operation assistance screen including a manually operated device selection section and a control content display section that displays control content assigned to the operation switches of the manual operation mechanism for a selected manually operated device; and a control device that connects the control unit of an identified control target device and the operation switches of the manual operation mechanism by receiving a control target device switching signal identified by operation of the manually operated device selection section.

A processing system (10) and corresponding method (158) are provided for processing workpieces (WP), including food items, to cut and remove undesirable components from the food items and/or portion the food items while being conveyed on a conveyor system (12). An X-ray scanning station (14) is located on an upstream conveyor section (20) to ascertain size and/or shape parameters of the food items as well as the location of any undesirable components of the food items, such as bones, fat or cartilage. Thereafter the food items are transferred to a downstream conveyor (20) at which is located an optical scanner (102) to ascertain the size and/or shape parameters of the food items. The results of the X-ray and optical scanning are transmitted to a processor (18) to confirm that the food item scanned by the optical scanner is the same as that previously scanned by the X-ray scanner. Once this identity is confirmed, if required, the data from the X-ray scanner is translated or transformed onto the data from the optical scanner. Such translation may include one or more of the shifting of the food items in the X and/or Y direction, rotation of the food item, scaling of the size of the food item, and sheer distortion of the food item. Next, the location of the undesirable material within the food item is mapped from the X-ray scanning data onto the optical scanning data. Thereafter, the undesirable material is removed by a cutter(s) (28). The food item may also (or alternatively) been portioned by the cutter(s) (28).

A method and apparatus for dimensioning an object carried by an automated pallet mover is disclosed. An example includes an image sensor configured to capture image data representative of a dimensioning area. A dimensioning coordinator is remotely located from an automated transportation system capable of moving the automated pallet mover. The dimensioning coordinator detects a dimensioning trigger condition associated with the pallet mover and sends first instructions to the automated transportation system to move the vehicle to the dimensioning area, and second instructions to coordinate movement of the vehicle and image capture operation to perform dimensioning on the object.

Systems, methods and computer-readable media for automating the restocking of shelves process by sending a notification when a product on a shelf has reached, or will reach, an undesired level of emptiness. This is determined using imaging sensors, such as cameras, which can calculate how full or empty a respective shelf is and predict when the shelf will need to be restocked. When the restocking time arrives, the notification can be sent to automated systems, which automatically cause new products to be stocked on the shelf via a pneumatic pipe system.

A dispatch system and a dispatch method for manufacturing mold are provided. The dispatch system includes a control unit, a mold material storage unit, a processing cutter storage unit, an object pick-and-place and transfer unit, a mold processing unit and a mold product storage unit. The mold material storage unit includes many unprocessed mold materials. The processing cutter storage unit includes many processing cutters. The object pick-and-place and transfer unit is electrically connected to the control unit and disposed between the mold material storage unit and the processing cutter storage unit. One of the unprocessed mold materials and one of the processing cutters are transferred to the mold processing unit by the object pick-and-place and transfer unit, the unprocessed mold material is processed to form a mold product by the mold processing unit, and the mold product is transferred to the mold product storage unit.

The present invention provides an automated modular system and method for production of biopolymers including DNA and RNA. The system and method automates the complete production process for biopolymers. Modular equipment is provided for performing production steps with the individual modules arrange in a linear array. Each module includes a control system and can be rack mounted. One side of the array of modules provides connections for power, gas, vacuum and reagents and is accessible to technicians. On the other side of the array of modules a robotic transport system is provided for transporting materials between module interfaces. The elimination of the requirement for human intervention at multiple steps in the production process significantly decreases the costs of biopolymer production and reduces unnecessary complexity and sources of quality variation.

Plant (1) for additively manufacturing at least one three-dimensional object (2), comprising at least one process station (3a-3c) being configured to perform an additive manufacturing process and/or at least one preprocessing process for an additive manufacturing process and/or at least one postprocessing process for an additive manufacturing process; at least one conveying device (19) configured to convey an item (20) between at least two positions (P1, P2) of the plant (1), the conveying device (19) comprising at least one conveying element (22), the at least one conveying element (22) being at least partially bound to ground (23), and at least one conveying carriage (24) being connectable or connected with the conveying element (22) so as to be moveable between at least two positions (P1, P2) of the plant (1), the at least one conveying carriage (24) comprising at least one supporting interface (25) for supporting at least one item (20).