A manufacturing system including an automated storage and retrieval system (ASRS) structure with a three-dimensional array of storage locations distributed throughout a two-dimensional footprint of the ASRS structure at multiple storage levels; workpieces stored within the storage locations of the ASRS structure; robotic storage retrieval vehicles (RSRVs) navigable within the ASRS structure in three dimensions to access the storage locations, and multiple manufacturing cells positioned outside the ASRS structure, is provided. The manufacturing system includes a track structure attached to the ASRS structure and defining one or more travel paths traversable by the RSRVs from the ASRS structure. The same fleet of RSRVs that is navigable within the ASRS structure is operable to deliver the workpieces to the manufacturing cells. One or more of the manufacturing cells are positioned along the track structure, thereby receiving convenient access to the workpieces along with associated tool pieces and workpiece supports for manufacturing goods.

Package sorting systems and methods of use are disclosed herein. An example system includes a platform of a vehicle, where the platform is arranged as a grid having a plurality of slots (including an open slot and a target slot). A plurality of slabs can be placed into the grid except for in the open slot. A slab moving assembly is used, to move the slabs in order to place a selected slab into the target slot on the platform.

A system for picking items from a containerised storage system is described. The items are stored in storage bins in stacks within a framework comprising a grid system disposed above the stacks of bins. Robotic devices are disposed on the grid, the devices acting so as to pick containers from the stacks of bins. The storage system is provided with at least one picking device for picking items from bins and depositing them directly in delivery containers DT.

A container-handling vehicle for picking up storage containers from a three-dimensional grid of an underlying storage system includes a first set of wheels arranged at opposite sides of a vehicle body, for moving the vehicle along a first direction on the grid; a second set of wheels arranged at opposite sides of the vehicle body, for moving the vehicle along a second direction on the grid, the second direction being perpendicular to the first direction; and the first set of wheels displaceable in a vertical direction between a first position, wherein the first set of wheels allow movement of the vehicle along the first direction, and a second position, wherein the second set of wheels allow movement of the vehicle along the second direction. The vehicle body surrounds a cavity within which at least a first lifting device and a second lifting device are positioned adjacent to each other, each lifting device is arranged to lift a storage container from the grid and into the cavity, such that a bottom of the storage container is at a level above the lowest level of the second set of wheels.

A load handling device for lifting and moving containers stacked in a storage system a grid framework structure, the load handling device including: a vehicle body housing a driving mechanism operatively arranged for moving the load handling device on the grid framework structure; a lifting device having a lifting drive assembly and a grabber device configured to releasably grip a container and lift the container from the stack into a container-receiving space; are chargeable power source electrically coupled to an electrical charge point for electrically coupling to a charge head of a charge station wherein; the electrical charge point includes a charge collector connectable to the charge head of the charge station under action of a magnet.

Provided are a parcel sorting system and method. The parcel sorting system is arranged in layers and includes: a parcel sorting layer located on an upper layer of the parcel sorting system, a moveable container carrying layer located on a lower layer of the parcel sorting system, a parcel delivery robot and a control device. The parcel sorting layer includes a modular entity platform that is a physical platform formed by splicing multiple splicable units and used for sorting parcels. The modular entity platform includes multiple delivery lattices arranged in an array and a traveling area constituted by gaps between the lattices and used for the parcel delivery robot traveling. One delivery lattices corresponds to one or more delivery path directions. The moveable container carrying layer includes multiple moveable containers, and a part of the containers are located below the lattices and receive the parcel from the parcel sorting layer.

A storage system is disclosed where goods can be stored in containers and the containers are stored in stacks. Above the stacks runs a grid network of rails (e.g., tracks) on which load handling devices can run. To take containers from the stacks and deposit then at alternative locations in the stacks or deposit then at stations where goods may be picked. The framework may be provided with one or more of the following exemplary services: power, power control, heating, lighting, cooling, sensors, and data logging devices. The provision of these services within the framework rather than across the system as a whole, can allow for flexibility in storage whilst reducing cost and inefficiency.

A processing system for processing objects using a programmable motion device is disclosed. The processing system includes a perception unit for perceiving identifying indicia representative of an identity of a plurality of objects received from an input conveyance system, and an acquisition system for acquiring an object from the plurality of objects at an input area using an end effector of the programmable motion device. The programmable motion device is adapted for assisting in the delivery of the object to an identified processing location. The identified processing location is associated with the identifying indicia and the identified processing location is provided as one of a plurality of processing locations. The system also includes a delivery system for receiving the object in a carrier and for delivering the object toward the identified processing location.

The present disclosure provides an improved cogwheel permitting enhanced meshing of cogwheels when operating perpendicularly. Exemplary embodiments introduce a multi-cogwheel design with specific dimensions and tooth profiles to permit perpendicular engagement of cogwheels whilst permitting translation of such cogwheels.

A multi-tiered automated parcel sortation system is utilized to sort parcels according to a common destination. A first tier includes an automated sorter configured to transport parcels from a source location to a release destination. A second tier includes accumulation containers each associated with a shipping destination, and the release destination within the first tier is a positioned directly above the accumulation container associated with the shipping destination of the parcel. Once transported to the release destination, a parcel is released into the accumulation container, and once the accumulation container is filled, the accumulation of parcels within the container is released into a third tier, which may include conveyors or autonomous guided vehicles with transport containers. In the third tier, the parcels are transported away for further processing.