Embodiments herein describe a DTG printing environment that uses autonomous robots to move garments between DTG processing stages (e.g., retrieval stages, pretreatment stages, printing stages, drying stages, etc.). Doing so removes the dependency of DTG printing process on the stage that consumes the most time. In one embodiment, the DTG processing stages or the autonomous robot include an actuator for moving the garment and the DTG processing stage closer together. In one embodiment, the processing stage includes a lift (e.g., an actuator) that lifts a detachable carrier from the robot on which the garment is mounted. The lift can level and rotate the detachable carrier to provide a fine alignment between the garment and the DTG processing stage. While a lift is specifically disclosed, in other embodiments, the actuator could be disposed on the robot to lift up the garment.

Systems and methods are provided for utilizing rules for placement of objects in storage in a manner that improves retrieval times relative to a default ordering utilized by an object storage system. For example, a request to store an object in a persistent storage of a data storage system may be received, metadata associated with the request may then be parsed to identify a signal for placement of the object within the persistent storage, and a rule may be identified for placement of objects associated with that signal, such as by indicating a desired grouping or ordering of objects associated with the signal. A particular storage location for the object may then be determined within the persistent storage based at least in part on the signal, the rule, and previously determined storage locations of one or more other data objects associated with the signal.

A method for retrieving an inventory item based on a handling robot, where the handling robot includes: a storage frame; and a material handling device installed on the storage frame, and including a telescopic arm and a manipulator installed to the telescopic arm; and the method for retrieving an inventory item includes: driving, by the telescopic arm, the manipulator to extend to a preset position of warehouse shelf along a preset horizontal reference line; loading, by the manipulator that is remained on the reference line, the inventory item located in the preset position; driving, by the telescopic arm, the manipulator loaded with the inventory item to move to the storage frame along the reference line; and unloading, by the manipulator that is remained on the reference line, the inventory item to the storage frame.

An unloading arrangement, an unloading station, and a method of unloading an item (5) from a storage container (6), comprising: a delivery vehicle (30); a storage container (6) carried by the delivery vehicle (30); and an unloading station (10) for unloading an item (5) from the storage container (6) while it is being carried by the delivery vehicle (30) in an automatic storage and retrieval system (1), the unloading station (10) comprising: an unloading device (40); and a destination conveyor (60) configured to convey the item (5) to a target destination (TD), wherein the unloading device (40) is configured to move the item (5) through a side opening of the storage container (6) to the destination conveyor (60).

Disclosed are a parts delivery system and a method of operating the same. The parts delivery system includes a production line configured to receive parts and assemble a finished product, a parts loading site configured to have a space where the parts are loaded; a parts transportation unit configured to load the parts in the parts loading site or discharge the parts from the parts loading site to supply the parts to the production line, and a processor configured to provide virtual space data on the parts loading site, to establish a parts loading schedule and a parts discharging schedule on the virtual space data according to an assembly schedule of the finished product of the production line, and to control the parts transportation unit to load or discharge the parts in the actual parts loading site according to the parts loading schedule and the parts discharging schedule.

A variety of vehicle-based and warehouse-based solutions are provided to increase the adaptability, utility, and efficiency of materials handling vehicles in the warehouse environment, such as a materials handling vehicle comprising a hand-held drive unit comprising a user interface and an operational command generator responsive to the user interface. The hand-held drive unit is configured to send operational commands generated in response to user input at the user interface to the vehicular controller(s) to control operational functions of the traction control unit, the braking system, the steering assembly, the mast assembly, the picking attachment, or combinations thereof.

A racking for storing articles having guiding tracks and a rail vehicle, which may be moved on the guiding tracks for storing and retrieving the articles, wherein the guiding tracks merge in an intersection area. Within the guiding tracks there are formed current bars and at the rail vehicle there are formed current receivers engaging with the current bars and supplying the rail vehicle in the guiding tracks with energy. The intersection area is free of current bars. The rail vehicle has an intersection sensor, which is configured to detect whether the rail vehicle is within the intersection area. The vehicle control is configured to switch the rail vehicle, on the basis of the signals of the intersection sensor and the voltage in the guiding tracks, into different operation modes.

A system may include a vehicle for delivering items and a moveable track that cooperates with the vehicle. The moveable track may cooperate with a storage system having storage locations for storing items. The vehicle may drive into the moveable track and lift the track using a vertical drive mechanism. The vehicle may include a horizontal drive system operable to drive the vehicle horizontally along the ground to carry the moveable track to a position adjacent the storage location. The vehicle may operate the vertical drive system to drop the moveable track adjacent the storage system. Additionally, the vehicle may operate the vertical drive to drive up the moveable track to an elevated position adjacent one of the storage locations in the storage system. The vehicle may include a transfer mechanism for transferring items between the vehicle and the storage location while the vehicle is in the elevated position.

Embodiments herein describe a DTG printing environment that uses autonomous robots to move garments between DTG processing stages (e.g., retrieval stages, pretreatment stages, printing stages, drying stages, etc.). Doing so removes the dependency of DTG printing process on the stage that consumes the most time. In one embodiment, the DTG processing stages or the autonomous robot include an actuator for moving the garment and the DTG processing stage closer together. In one embodiment, the processing stage includes a lift (e.g., an actuator) that lifts a detachable carrier from the robot on which the garment is mounted. The lift can level and rotate the detachable carrier to provide a fine alignment between the garment and the DTG processing stage. While a lift is specifically disclosed, in other embodiments, the actuator could be disposed on the robot to lift up the garment.

A method and system for piece-picking or piece put-away within a logistics facility. The system includes a central server and at least one mobile manipulation robot. The central server is configured to communicate with the robots to send and receive piece-picking data which includes a unique identification for each piece to be picked, a location within the logistics facility of the pieces to be picked, and a route for the robot to take within the logistics facility. The robots can then autonomously navigate and position themselves within the logistics facility by recognition of landmarks by at least one of a plurality of sensors. The sensors also provide signals related to detection, identification, and location of a piece to be picked or put-away, and processors on the robots analyze the sensor information to generate movements of a unique articulated arm and end effector on the robot to pick or put-away the piece.