A system for performing measurements in storage containers for storing items includes a framework structure. The storage containers are stored in an automated storage system. The framework structure forms a three-dimensional storage grid structure for storing the storage containers. The grid structure forms vertical storage columns each having a horizontal area defined by the size of an access opening to the vertical storage columns between rails of a rail system. The rail system is arranged on top of the framework structure. The rail system provides available routes for container handling vehicles handling and transferring the storage containers to and from the storage columns. Each vehicle includes a vehicle controller communicating with a central computer system controlling the operation of the storage system. A container handling platform of a container handling vehicle includes measuring equipment configured to perform measurements in containers and includes a communication unit configured to communicate measurement data to a computer system.

An automated storage and retrieval system includes a framework structure constructed of a plurality of upright members connected by horizontal members to define a storage grid of storage columns, within which storage columns may be stacked a plurality of storage containers. The framework structure has a rail system arranged at the upper level of the framework structure, with parallel rails in a first direction and parallel rails in a second direction perpendicular to the first direction, upon which rails a plurality of wheeled container handling vehicles travel. The container handling vehicles are equipped with a gripping and lifting device for removing storage containers from the storage columns and replacing the storage containers in the storage columns. The upright members of the framework structure have corner sections directed towards an interior of a particular storage column. The corner sections include two vertically elongated, perpendicular corner guiding plates. The corner guiding plates of the upright members are proximate to a storage column forming a guide for corners of the storage containers stored in that storage column A bracing system includes a plurality of plate members mounted between adjacent upright members. The bracing plate members include a plate segment removably mounted between two retaining profiles. Each retaining profile has a shape adapted to engage an upright member. The retaining profiles of the plate members have a box shape adapted to be securely inserted between and essentially occupy the space between the corner guiding plates of two adjacent corner sections of an upright member. A plate segment of plate member is arranged to be connected to a flange of the inserted retaining profiles. The bracing plate members are arranged to provide structural support stability for the framework structure. The guiding plates have inwardly projecting ribs that engage corresponding grooves of the retaining profiles by snap fit.

A storage system includes a storage device and a transfer device. The storage device includes a guide bar, a plurality of upper shelves connected to the guide bar, the plurality of upper shelves storing a material to be transferred, a plurality of lower shelves disposed under the plurality of upper shelves, the plurality of lower shelves storing the material, a plurality of guides connected to the plurality of upper shelves, and a shelf returning device connected to a selected upper shelf from among the plurality of upper shelves. The transfer device includes a body, a drive module attached to the body, the drive module moving the transfer device to be adjacent to the storage device, a handling module attached to the body, the handling module handling the material, and a shelf moving module attached to the body or the handling module, the shelf moving module contacting a selected guide from among the plurality of guides.

A measuring system for monitoring atmospheric conditions in an automated storage and retrieval system including a framework structure. The framework structure forms a three-dimensional storage grid structure for storing storage containers for storing items. The grid structure forms vertical storage columns each having a horizontal area defined by the size of an access opening of the vertical storage columns. A rail system is arranged on the framework structure defining the circumference of each access opening on top of each storage column. The rail system provides available routes for container handling vehicles handling and transferring the storage containers to and from the storage columns. The at least one container handling vehicle has at least one rechargeable power source. A container handling platform has a first set of grippers for handling the storage containers. The measuring system includes at least one box-shaped measuring unit of the same size and features as a storage container. The box-shaped measuring unit includes measuring equipment for measuring at least one atmospheric condition within the grid structure, a transmitter for transmitting measurement data to a computer system, at least one rechargeable power source, and a data recorder for recording the measurement data. The box-shaped measuring unit includes at least one piece of measuring equipment on all sides of the box-shaped measuring unit.

A method and apparatus for dispensing and retrieving products is provided. A system may include: a grasping head; first and second grasping members, each grasping member comprising: a top member; a post member; and first and second grasping fingers, where the first and second grasping fingers extend from the post member and are spaced apart from the top member by a predetermined distance, where the first and second grasping members are connected to the grasping head, where at least one of the first and second grasping members is movably connected to the grasping head, where the at least one of the first and second grasping members is movable relative to the other of the first and second grasping members.

A robotic object handling system and robotic load handling device for operation thereon is disclosed. The object handling system includes a number of robotic load handling devices operational on a grid-like structure, the structure having sets of parallel tracks, disposed above a hive of stacked bins. The bins contain inventory items to be picked by the system. Load handling devices capable of carrying multiple bins of a single grid-spacing size or single bins of a multiple grid spacings are operational on the grid and retrieve and transport bins under the control of a computerised order picking utility.

An automated storage and retrieval system includes a track system including a first set of tracks arranged in a horizontal plane and extending in a first direction, and a second set of tracks arranged in the horizontal plane and extending in a second direction that is orthogonal to the first direction. The first set of tracks and the second set of tracks form a grid pattern in the horizontal plane including a plurality of adjacent grid cells. Each grid cell includes an opening defined by the first set of tracks and the second set of tracks such that the track system includes a plurality of openings. A plurality of storage containers are arranged in columns beneath the track system such that the storage containers are located vertically below the openings. A plurality of container handling vehicles for lifting and moving the storage containers are configured to move on the track system and access the storage containers via the openings. Each container handling vehicle of the container handling vehicles includes a lower part in contact with the track system and an upper part. The lower part has a width and a length that form a vehicle footprint. The vehicle footprint of the lower part has dimensions smaller than the opening such that a contact area of the container handling vehicle does not extend into an adjacent grid cell. The upper part, which is disposed vertically above the lower part, includes a protruding section and a recessed section. The protruding section is configured to extend beyond the lower part into the adjacent grid cell. The recessed section is of a complimentary shape to the protruding section such that the recessed section is configured to receive other protruding sections of other vehicles of the container handling vehicles. The lower part further includes a storage space configured to accommodate a storage container of the storage containers.

A system includes an article supply location, wherein the article supply location includes a plurality of articles to be sorted, first and second transport vehicles, each having a first position in which an article is stowed about the vehicle and a second position in which the article is deposited into a proximal container. And a control system. The control system is configured to receive an order for a plurality of disparate articles, determine one destination container of a plurality of destination containers to direct the transport vehicle to deposit a selected article, direct the first transport vehicle to transport a selected article to the destination container and deposit the article by manipulation of the first transport vehicle from the first position to the second position for deposit of the selected article in the destination container.

An automated storage and retrieval system includes a rail system with a first set of parallel rails extending in a first direction and a second set of parallel rails extending in second direction. The second direction is perpendicular to the first direction. The system includes a plurality of container handling vehicles on the rail system operable to handle storage containers. Each container handling vehicle includes a positioning node and a local controller adapted to control movements of the container handling vehicle. The system includes a positioning system comprising at least three reference positioning nodes spaced in fixed positions on and/or proximate the rail system. The positioning system is adapted to determine a position on the rail system for each of the container handling vehicles based on signal measurements between the positioning node of each container handling vehicle and the at least three reference positioning nodes. A control system is adapted to communicate with each local controller in each container handling vehicle and the positioning system. The control system is adapted to: instruct a first container handling vehicle to move to a target position, repeatedly receive position data from the positioning system of a position of the first container handling vehicle and repeatedly receive position data from the positioning system of a position of a second container handling vehicle, and instruct the second container handling vehicle to move with and follow the first container handling vehicle within a predetermined separation from the first container handling vehicle based on the received position data of the positions of the first and second container handling vehicles.

A container handling vehicle with a cantilever solution operates on an automated storage and retrieval system. The automated storage and retrieval system includes a framework structure forming a three-dimensional storage grid structure for storing storage containers for storing items. The grid structure forms vertical storage columns each having a horizontal area defined by the size of an access opening of the vertical storage columns. A rail system is arranged on the framework structure, rails of the rail system extending in an X-direction and a Y-direction to define a grid and to define a perimeter of each access opening on top of each storage column. The rail system provides available routes for container handling vehicles handling and transferring the storage containers to and from the storage columns. Each rail has a first track and a parallel second track allowing two container handling vehicles to pass each other using the same rail. Each vehicle communicates with a central computer system controlling the operation. At least one container handling vehicle has a container handling platform with a set of grippers for handling the storage containers. The wheels are on a cantilever side of the container handling vehicle, used for manoeuvring the container handling vehicle in the Y-direction, are positioned or are positionable with respect to the container handling vehicle to allow them to use an outer track of a rail in the Y-direction to manoeuvre the container handling vehicle when the wheels on an opposite side of the container handling vehicle are using an inner track of an adjacent rail in the Y-direction.