A robotic pack station is disclosed. The robotic pack station automates the transfer of items from a tote or bin to a shipping container such as a box in a warehouse, storage or sales facility. The robotic pack station includes system and method components, and includes a work cell with a robotic arm, machine vision or sensing system, a conveyor and pack platform. Imaging of the contents of the tote with a scan tunnel and connectivity with a sorter device allows for the operation of multiple robotic pack stations, each with a specialized function such as a small box line, a medium box line, and the like.

A system for unloading parcels from a cargo area includes: an extendible conveyor; a transfer conveyor for conveying parcels to the extendible conveyor; and a mobile robot assembly configured to engage and transfer parcels in the cargo area onto the transfer conveyor. The mobile robot assembly repeatedly advances and transfers parcels in the cargo area to the transfer conveyor. As the mobile robot assembly advances within the cargo area, the transfer conveyor and the extendible conveyor follow to provide a pathway along which parcels transferred by the mobile robot assembly can be transferred out of the cargo area. The mobile robot assembly includes: a mobile base for repositioning the mobile robot assembly; a framework mounted to the mobile base; a first robot and a second robot, each mounted for vertical movement with respect to the framework and configured to engage and transfer parcels; and a vision and control subsystem.

A food preparation system arranged in a kitchen includes a gantry fixed with the kitchen, at least one robot arm having an end effector supported on a base in the kitchen, where the base is movably mounted on the gantry, defining a reaching distance of the robot from the end effector to the base, along a travel path of the base on the gantry, a storage container arranged in the kitchen, within the reaching distance of the at least one robot arm, and configured for storing a food item, at least one ingredient distribution device arranged in the kitchen, within the reaching distance of the at least one robot arm, and configured for dispensing at least one ingredient on the food item, and an oven arranged in the kitchen, within the reaching distance of the at least one robot arm, and configured for baking the food item.

A waste sorting robot can include a manipulator comprising a suction gripper for interacting with one or more waste objects to be sorted within a working area, and wherein the manipulator is moveable within the working area. There is a controller configured to send control instructions to the manipulator. At least one pressure sensor is in fluid communication with the suction gripper and configured to generate a pressure signal in dependence on a fluid pressure in the suction gripper. The controller is configured to receive the pressure signal and to determine manipulator instructions in dependence on the pressure signal.

A robot control system includes: a selector configured to perform a selection of a task object from among a plurality of workpieces by using a first vision sensor; and an operation control section configured to control a robot to perform a task on the task object by using a tool. The selection and the task are executed simultaneously and in parallel, the selector transmits the information of the selected task object to the operation control section before the task, and the operation control section controls the robot based on the transmitted information of the task object.

Systems, methods, and computer-readable media are disclosed for container transporters and related item manipulation devices. In one embodiment, an example item manipulation device may include a support platform, and a conveyance surface attached to the support platform and configured to convey a container at least a portion of a distance from a first side of the support platform to a second side of the support platform, where the conveyance surface defines at least a portion of a container passage through which a container can be conveyed. The item manipulation device may include a manipulator comprising a first arm disposed along a longitudinal axis of the item manipulation device and a second arm disposed along the longitudinal axis of the item manipulation device, where the manipulator is engageable with the container to move the container at least partially onto the conveyance surface.

Systems, methods, and computer-readable media are disclosed for camera-based tracking systems for item sortation systems. In one embodiment, an example method may include determining, by a controller using first image data from a camera configured to image an aisle of an item sortation machine, a first item disposed on a first shuttle at a first location, where the first shuttle is in motion to a first designated drop off location, determining a first shuttle identifier of the first shuttle, and determining the first designated drop off location using the first shuttle identifier. Example methods may include determining that the first item has fallen onto a floor of the aisle, and determining that the first item was not delivered to the first designated drop off location.

An automated truck unloader for unloading/unpacking product, such as boxes or cases, from trailers and containers is disclosed. In one embodiment, a mobile base structure provides a support framework for a drive subassembly, conveyance subassembly, an industrial robot, a distance measurement subassembly, and a control subassembly. Under the operation of the control subassembly, an industrial robot having a suction cup-based gripper arm selectively removes boxes from the trailer and places the boxes on a powered transportation path. The control subassembly coordinates the selective articulated movement of the industrial robot and the activation of the drive subassembly based upon a perception-based robotic manipulation system.

An article processing apparatus includes: a configuration determination unit configured to determine a configuration of at least one transport unit including articles, and stacked article groups each including a pallet, and at least one of the articles placed on the pallet, wherein the at least one of the articles is placed on the pallet in a manner that allows a pallet of another article group to be placed thereon, excluding uppermost one of the stacked article groups; a palletizing mechanism configured to place the at least one of the articles on the pallet so as to form each of the article groups included in the transport unit whose configuration is determined by the configuration determination unit; and a stacking mechanism configured to stack the article groups formed by the palletizing mechanism so as to form the transport unit determined by the configuration determination unit.

A method of inverting workpieces in a mass production process includes: advancing an end effector in electronic synchronization with advancement of a carrier to synchronize arrival of the carrier at a stop position with arrival of the end effector at an unloading position, in which the end effector is in alignment with a workpiece held by the carrier for engaging the workpiece; while the end effector is in engagement with the workpiece, retracting the end effector away from the carrier to unload the workpiece from the carrier and advancing the end effector back toward the carrier to load the workpiece back into the carrier; and rotating the end effector relative to the carrier to invert the workpiece in electronic synchronization with the retracting and advancing of the end effector for loading the workpiece back into the carrier when inverted.