An automated storage and retrieval system includes a grid-based rail structure and a plurality of remotely operated delivery vehicles arranged to operate on the grid-based rail structure. The automated storage and retrieval system includes a locking device arranged in a zone of the grid-based rail structure where a human and/or a robotic operator is permitted to interact with the remotely operated vehicle or contents of a storage container that the remotely operated vehicle is carrying. The locking device is arranged to latch to a motorized vehicle body of the remotely operated delivery vehicle, and to lock the remotely operated delivery vehicle against accidental displacement prior to interaction with the human and/or robotic operator. The locking device is arranged to unlock the remotely operated delivery vehicle once interaction with the human and/or robotic operator is no longer required.

A robotic picking device for picking items from a containerised storage system wherein items are stored in storage bins in stacks within a framework having a grid system disposed above the stacks of bins. Robotic picking devices are disposed on the grid, the devices acting 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.

An automated grid based storage and retrieval system includes a framework structure including upright members and a grid of horizontal rails provided at upper ends of the upright members. The framework structure defines at least one storage volume below the horizontal rails. The at least one storage volume is open against the horizontal rails such that storage container vehicles may lower and raise storage containers into and out of the storage volume. The at least one storage volume includes a plurality of storage columns arranged adjacent one another, a plurality of walls surrounding the at least one storage volume; a void extending beneath the storage columns; and a cooler system adapted to draw air from the void, cool the air, and release the cooled air into an air release area arranged below the horizontal rails. The cooler system is arranged within an cooler enclosure arranged inside the plurality of walls and adjacent the plurality of storage columns. The cooler enclosure includes at least one opening from the void for the cooler system to draw air from the void, and a conduit for releasing the cooled air in the air release area.

A pallet transport means for transporting a plurality of pallets includes a base frame configured to receive the plurality of pallets, and at least two lifting units arranged oppositely on the base frame. Each lifting unit has a plurality of spaced apart brackets which are connected to one another and which are configured in each case to receive a respective pallet in pairs in an opposite manner, and can be moved on one hand orthogonally and on the other hand parallel in relation to the base frame.

A remotely-operated vehicle assembly for picking up storage bins from a storage system and a method for changing vehicle direction includes a body displaying a cavity, a lifting device connected to the body for lifting the bin into the cavity, a displacement arrangement including a displacement motor which provides power to displace one or both of first and second sets of vehicle wheels between a displaced state where the relevant vehicle wheels are displaced away from the underlying system during use, and a non-displaced state where the relevant vehicle wheels are in contact with the underlying system during use, and driving wheels coupled to the displacement arrangement. The driving wheels further includes first and second sets of vehicle wheels connected to the body allowing movement of the vehicle along first and second directions, respectively, within the system. The first and second directions are perpendicular.

A conveying module includes a base structure; a first conveying device to convey a unit of goods in a first conveying direction (x) in the horizontal; a second conveying device to convey a unit of goods in a second conveying direction (y) in the horizontal, wherein the second conveying direction runs substantially perpendicular to the first conveying direction; a carrier structure to carry a unit of goods; a first lifting device to raise and/or lower the first conveying device in the vertical (z) between a lower position and an upper position; and a second lifting device to raise and/or lower the second conveying device in the vertical (z) between a lower position and an upper position; wherein a unit of goods located on the conveying module rests on the carrier structure when the first conveying device and the second conveying device are in the lower position.

A storage system is described where goods are stored in containers and the containers are stored in stacks. Above the stacks runs a grid network of tracks on which load handling devices run. The load handling devices take containers from the stacks and deposit then at alternative locations in the stacks or deposit then at stations where goods may be picked out. Each container may be provided with connectors having a push fit male connector located at a top edge of the container and a female connector at a bottom edge of the container. Adjacent containers in a stack can be linked by routing means, which form moldings on each container. The connectors can also have spring-loaded contacts. The provision of these services within individual containers rather than across the system as a whole, allows for flexibility in storage whilst reducing cost and inefficiency.

An automatic storage and retrieval system is provided that is usable to sort, store and retrieve parcels for delivery. The system provides a multi-layered rail system allowing a high-density storage system for parcels. In some aspects, the parcels may be sorted between parcel containers in different layers, and in some aspects parcel containers may be transferred between layers, allowing individual parcels to be logically sorted and placed within a parcel container according to a delivery destination. Once at a delivery destination, the system may be used to load an unmanned delivery device, such as a robot, with a parcel container associated with the delivery destination.

A system and method are provided for decanting inbound goods into optimally dimensioned compartments of totes for storage in an ASRS storage system. The system includes decant workstations with multiple tote decant positions each dedicated to receive totes having a compartment configuration different than for those at the other decant positions. The method includes presenting a decant operator with multiple totes such that the operator substantially always has an empty or partially filled compartment of each available compartment size which to place inbound items into. A warehouse control system guides the operator to which presented tote and which compartment within that tote to place the items. The warehouse control system monitors each of the totes at the decant positions and once a tote's compartments are all filled to capacity, that tote is returned to the storage system and replaced with another tote having an identical compartment configuration.

A system for storing and transporting storage containers includes an automated storage and retrieval grid including vertical members defining multiple storage columns for storing storage containers on top of each other in vertical stacks. The vertical members are interconnected at their upper ends by a container handling vehicle rail system arranged to guide at least one container handling vehicle being configured to raise storage containers from, and lower storage containers into, the storage columns, and to transport the storage containers above the storage columns. The container handling vehicle rail system includes a first set of parallel rails arranged in a first horizontal plane and extending in a first direction, and a second set of parallel rails arranged in the first horizontal plane and extending in a second direction which is orthogonal to the first direction, which first and second sets of rails form a grid pattern in the first horizontal plane including a plurality of adjacent container handling vehicle grid cells. Each container handling vehicle grid cell includes a container handling vehicle grid opening defined by a pair of neighboring rails of the first set of rails and a pair of neighboring rails of the second set of rails. A transfer column is adapted for transport of a storage container between the container handling vehicle and a delivery space is situated at a lower end of the transfer column. A delivery system includes a first delivery rail system having at least one set of parallel rails arranged in a second horizontal plane guiding at least one delivery vehicle thereon. The delivery vehicle is adapted to receive and/or deliver a storage container at a storage container delivery location arranged below the delivery space of the transfer column and to move between the storage container delivery location and a second location, the first delivery rail system covers at least an area extending from the storage container delivery location to the second location. A vehicle lift device is for transfer of the at least one delivery vehicle between a first lift stop position adjacent the second location in the second horizontal plane and a second lift stop position adjacent a third location arranged in a third horizontal plane being at a different vertical level than the second horizontal plane.