A container accessing station for accessing a storage container of an automated storage and retrieval grid. The container accessing station comprising: an access opening through which a human and/or robot may access contents of the storage container; a base opening; and a lifting device arranged to retrieve the storage container from a first level beneath the base opening and lift it up through the base opening to a second level so that the storage container may be accessed through the access opening.

The invention is also directed to a container accessing system and a method thereof.

A logistics tower includes a vertical storage cell column, a vertical retrieval system and a horizontal shuttle system. The vertical storage cell column includes an elevator shaft extending therethrough and a plurality of storage modules arranged around the elevator shaft. The vertical retrieval system includes a winch and a robotic bin handier. The robotic bin handler is moveably by the winch within the elevator shaft of the vertical storage cell column. The robotic bin handler includes a carnage assembly that extends inwardly and outwardly therefrom to access and retrieve storage bins from the storage modules arranged around the elevator shaft. The carriage assembly includes a gripping assembly that selectively couples and decouples the storage bin to the carriage of the robotic bin handler. The vertical retrieval system lowers the storage bin coupled to the carriage assembly to a. robotic shuttle situated on the horizontal shuttle system.

The present invention provides a storage system (1) comprising a storage grid structure (104) and multiple container handling vehicles (200,300), the storage grid structure comprises vertical column profiles (102) defining multiple storage columns (105), in which storage containers (106) can be stored one on top of another in vertical stacks (107), and at least one transfer column (119,120), the column profiles are interconnected at their upper ends by top rails (110,111) forming a horizontal top rail grid (108) upon which the container handling vehicles (200,300) may move in two perpendicular directions, the container handling vehicles are able to retrieve storage containers (106) from, and store storage containers in, the storage columns (105), and transport the storage containers on the storage grid structure, wherein the storage grid structure (104) comprises at least one horizontal transfer section (2); and the storage system comprises multiple container transfer vehicles (6) and transfer rails (110′,111) forming a transfer rail grid (5) upon which the container transfer vehicles (6) may move in at least one horizontal direction, and the transfer section (2) is arranged at a level below the top rail grid (108) and extends from an external side (12) of the storage grid structure (104) to a position below the at least one transfer column (119,120) and comprises at least a section of the transfer rail grid (5) upon which section the container transfer vehicles (6) may pass each other and move in two perpendicular horizontal directions; and each of the container transfer vehicles comprises a container carrier (38) for carrying a storage container (106) and a wheel arrangement (32a,32b) for moving the container transfer vehicle (6) in two perpendicular directions upon the transfer rail grid (5); and wherein the at least one transfer column (119,120) extends from the top rail grid (108) to the transfer section (2), such that a storage container (106) may be transferred between the top rail grid (108) and the container carrier of one of the container transfer vehicles (6).

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.

The storage system includes a base that supports a container for accommodating articles and a transport robot for transporting the container. The transport robot has a load unit that can load the container and a lift unit for moving the load unit in the vertical direction. The transport robot has a switch unit for switching between a state in which the base restricts the vertical movement of the container and a state in which the base does not restrict the vertical movement of the container. When the storage system increases the number of containers supported by the base, the lift unit moves the container to be stored from a position below the support position on the base to the support position in a state in which the base does not restrict the vertical movement of the container. After the container to be stored reaches the support position, the switch unit switches from a state in which the base does not restrict the vertical movement of the container to a state in which the base restricts the vertical movement of the container.

A smart locker automated transfer system includes one or more lockers, a transfer system, and an autonomous delivery robot. Each locker includes a retractable base plate configured to hold the package. The transfer system may include a rack and rail system, one or more conveyor belts, or both. The autonomous delivery robot may be configured to receive the package from the transfer system. The autonomous delivery robot may be configured to deliver the package to a destination.

An object processing system is disclosed that includes a plurality of track sections, and a plurality of remotely actuatable carriers for controlled movement along at least portions of the plurality of track sections, wherein each of the remotely controllable carriers is adapted to support and transport an object processing bin.

A method for operating a storage arrangement, in goods are inserted into the storage arrangement in an inbound delivery container at an incoming goods area, are removed from the inbound delivery container, are temporarily stored and are removed from the storage arrangement in a predetermined sequence in an outbound delivery container at an outgoing goods area. The goods are transferred from the inbound delivery container into a stackable packaging unit and the packaging unit is temporarily stored in a block storage unit. The block storage unit has multiple stacking compartments and each stacking compartment is designed to receive a stack of packaging units. The goods are removed from the block storage unit in a sequence predetermined by the outgoing goods area.

Disclosed is a first dispenser module with a product holder for holding a plurality of beverage cans and a dispensing mechanism for dispensing one beverage can of the plurality of beverage cans at a time in a dispensing direction from the product holder, wherein the product holder is arranged for holding the plurality of beverage cans with their central axes parallel to said product orientation direction. The dispensing mechanism has a retaining cam that is movable with at least a vector component in the production orientation direction between a retaining position for retaining the plurality of beverage cans and a release position for releasing the beverage cans from the product holder, wherein the retaining cam, in the retaining position, is arranged to be in the path of the top rim or the bottom rim of one of the beverage cans in the dispensing direction.

A warehousing apparatus including a temporary storage layer board used for providing a temporary storage station, and a plurality of shelves with each shelf including at least one storage layer board and a plurality of stand columns arranged at intervals in a horizontal direction. The storage layer board is spaced apart from the temporary storage layer board in a vertical direction by means of a stand column, and the storage layer board is used for providing a storage position, a first robot passage in which a first robot travels and a second robot passage in which a second robot travels.