An automated storage system for receiving, storing, and dispensing items is herein proposed. The system has an enclosure, which defines a storage volume, and a port which selectively connects the storage volume to the ambient space for deposit and retrieval of items. The system also includes a plurality of containers for containing at least one item being stored as well as a support structure for supporting the plurality of containers in the storage volume. The containers feature a base, an envelope extending from the base, and an opening opposing the base and providing access to an inner volume defined by the base and envelope for containing at least one item. The system includes a manipulator for transporting the containers between an access position at the port and a storage position at the support structure. Finally, the system includes a one-sided attachment interface between the container and the support structure for removably attach the container to the support structure in the storage position, in which the opening of the container is above the base.

Facilities for processing steel. One facility includes a line for producing packages; a plurality of stackable cassettes for receiving packages; a splitter subfacility; automated transfer apparatus; and an automated overhead crane. The line may be a slitting line with the packages being coils of steel, or a cut-to-length line with the packages being stacks of steel sheets. A premises of the facility comprises a loading area in which packages from the line are loaded into cassettes, a storage area in which cassettes are stored, and a transition zone including at least one transfer position. The automated transfer apparatus moves packages and/or cassettes between the transfer position and the splitter subfacility. The automated overhead crane moves cassettes between the storage area, the loading area, and the transition zone.

Facilities for processing steel. One facility includes a line for producing packages; a plurality of stackable cassettes for receiving packages; a splitter subfacility; automated transfer apparatus; and an automated overhead crane. The line may be a slitting line with the packages being coils of steel, or a cut-to-length line with the packages being stacks of steel sheets. A premises of the facility comprises a loading area in which packages from the line are loaded into cassettes, a storage area in which cassettes are stored, and a transition zone including at least one transfer position. The automated transfer apparatus moves packages and/or cassettes between the transfer position and the splitter subfacility. The automated overhead crane moves cassettes between the storage area, the loading area, and the transition zone.

An inverted carrier lift and method is disclosed. The inverted carrier lift includes a trolley movable along an overhead conveyor and a carrier for supporting a workpiece to undergo an assembly or manufacturing process. The carrier is movable relative to the trolley from a raised position to a lowered position by a motor mounted engaged with a lifting mechanism onboard the trolley. On rotation of the motor, the carrier and supported workpiece is lowered or raised to position the workpiece in the workstation for processing. The workpiece may be disengaged by the carrier for support of the workpiece by one of many different fixtures depending on the processing. Following processing, the workpiece is re-engaged by the carrier, moved to a raised position and the trolley is transferred to a subsequent workstation.

An inverted carrier lift and method is disclosed. The inverted carrier lift includes a trolley movable along an overhead conveyor and a carrier for supporting a workpiece to undergo an assembly or manufacturing process. The carrier is movable relative to the trolley from a raised position to a lowered position by a motor mounted engaged with a lifting mechanism onboard the trolley. On rotation of the motor, the carrier and supported workpiece is lowered or raised to position the workpiece in the workstation for processing. The workpiece may be disengaged by the carrier for support of the workpiece by one of many different fixtures depending on the processing. Following processing, the workpiece is re-engaged by the carrier, moved to a raised position and the trolley is transferred to a subsequent workstation.

A single deck pallet comprising a deck having a top for supporting a load and a bottom, at least four sides, the at least four sides comprising a first pair of opposed sides and a second pair of opposed sides. A plurality of intermediate spaced apart beams of the deck extending between (and preferably to) at least a first pair of opposed sides. A plurality of distributed primary props dependent from the deck and projecting below the bottom of the deck to aid in supporting the pallet on a surface. At least one beam extends between adjacent primary props and the primary props are horizontally spaced apart from each other and from said at least one beam so as to allow a tine of a forklift to pass in a linear direction parallel to the at least one beam between adjacent primary props to reach at least partially under and bear on the bottom of the deck and bear on the at least one beam.

A packaging system for high flexibility and speed box-last packaging comprises one or more dimensional scanning sensors that are configured to scan a group of one or more target products that are to be boxed and gather dimension information describing physical dimensions of the group of one or more target products. The system also comprises one or more packaging-production machines that are configured to generate custom-made packaging templates that conform to a pre-determined set of packaging template types. Additionally, the system comprises a packaging template buffer that comprises physically divided sections that contain multiple packaging templates selected from the pre-determined set of packaging template types that are generated by the one or more packaging-production machines. Each of the packaging templates are organized within the physically divided section based upon packaging template type.

A packaging system for high flexibility and speed box-last packaging comprises one or more dimensional scanning sensors that are configured to scan a group of one or more target products that are to be boxed and gather dimension information describing physical dimensions of the group of one or more target products. The system also comprises one or more packaging-production machines that are configured to generate custom-made packaging templates that conform to a pre-determined set of packaging template types. Additionally, the system comprises a packaging template buffer that comprises physically divided sections that contain multiple packaging templates selected from the pre-determined set of packaging template types that are generated by the one or more packaging-production machines. Each of the packaging templates are organized within the physically divided section based upon packaging template type.

A system and method for automated palletization of totes and cuboid containers includes an end effector having fingers projecting outwardly. The fingers may engage recesses in the totes. Alternatively, actuators on fixed fingers can move gripping surfaces into engagement with the totes or containers. Or actuators on a body of the end effector can move the fingers, which include gripping surfaces.

A system and method for automated palletization of totes and cuboid containers includes an end effector having fingers projecting outwardly. The fingers may engage recesses in the totes. Alternatively, actuators on fixed fingers can move gripping surfaces into engagement with the totes or containers. Or actuators on a body of the end effector can move the fingers, which include gripping surfaces.