A load handling device is disclosed for lifting and moving one or more containers stacked in a storage system having a grid framework structure supporting a pathway arranged in a grid pattern above stacks 1of containers, the load handling device including a vehicle body housing a driving; a lifting device including a lifting drive assembly and a grabber, wherein the lifting drive assembly and/or the driving mechanism includes at least one motor forming an electrical load; a rechargeable energy storage for providing energy to power the electrical load; and a charging system including a first part for charging the rechargeable energy storage including a charge receiving element on the vehicle body, and a second part for delivering energy to the electrical load; wherein the second part includes a DC/DC converter to supply a predetermined DC voltage across the electrical load.

Three-dimensional warehouse handling and dispatching systems, devices, and methods for implementing item picking are provided. In one aspect, a system includes: one or more control centers, one or more first handling devices, one or more second handling devices, at least one lifting device, and at least one three-dimensional warehouse including floors communicated by the at least one lifting device. The one or more control centers are configured to: determine, according to a handling task, a first handling device, a second handling device, and a lifting device for performing the handling task, and send a handling instruction for performing the handling task separately to the first handling device, the second handling device, and the lifting device, such that the lifting device is used to handle an item indicated in the handling instruction, and the first and second handling devices cooperate to transport the item in the at least one three-dimensional warehouse.

A vehicle for use in an inventory management system having a plurality of destination areas and a guide system includes a platform for receiving and transporting items to and from the destination areas, a plurality of motors, a first drive system, a second drive system, a transfer mechanism, and a clutch mechanism. The transfer system is configured to transfer and retrieve items to and from the destination areas, and the clutch mechanism is configured to engage and disengage the transfer mechanism from at least one of the motors, whereby the second drive system drives movement of the vehicle independently of the transfer mechanism.

A vehicle tilting device for tilting a delivery vehicle for increasing access to items from a storage container transported on the delivery vehicle. The vehicle tilting device comprises a base structure and a tiltable platform connected to the base structure, wherein the tiltable platform comprises guiding features adapted to guide the delivery vehicle onto the tiltable platform. The tiltable platform is arranged to be connected to a delivery grid cell of a delivery rail system such that that there is a path to and/or from the tiltable platform for the delivery vehicle via the delivery grid cell. The invention is also related to an access station, a delivery system and a method of accessing a storage container.

A container handling vehicle for lifting a storage container from an underlying framework structure includes a vehicle body and a container lifting assembly for lifting the storage container. The vehicle body includes a wheeled base, a support, and at least one cantilevered section. The wheeled base includes a first set of wheels, arranged on opposite sides of the vehicle body, for moving the vehicle along a first direction on a rail grid at a top level of the underlying framework structure, and a second set of wheels arranged on other opposite sides of the vehicle body, for moving the vehicle along a second direction on the rail grid, the second direction being perpendicular to the first direction. The support includes a lower end connected to the wheeled base and an upper portion connected to the cantilevered section. The container lifting assembly includes a lifting frame and a plurality of lifting bands. The lifting frame is for releasable connection to a storage container and suspended from the cantilevered section by the lifting bands, such that the lifting frame may be raised or lowered relative to the cantilevered section. The cantilevered section extends laterally from the upper portion of the support and is arranged to rotate horizontally about a vertical axis relative to the wheeled base between a first position and a second position. In the first position, the cantilevered section extends beyond the wheeled base, such that the lifting frame may retrieve or deliver a storage container from/to a storage column of the framework structure. In the second position the cantilevered section extends in an opposite direction relative to the direction in the first position. The support holds the cantilevered section above the wheeled base at a height corresponding to a height of multiple storage containers, such that a vertical distance between the lifting frame, when the lifting frame is in an upper position, and the lower end of the support is larger than the height of two storage containers stacked on top of each other.

An example method is carried out in a warehouse environment having a plurality of inventory items located therein, each having a corresponding on-item identifier. The method involves determining a target inventory item having a target on-item identifier. The method also involves determining that a first inventory item having a first on-item identifier is loaded onto a first robotic device. The method further involves transmitting a request to verify the first on-item identifier. The method still further involves receiving data captured by a sensor of the second robotic device. The method yet further involves (i) analyzing the received data to determine the first on-item identifier, (ii) comparing the first on-item identifier and the target on-item identifier, and (iii) responsive to comparing the first on-item identifier and the target on-item identifier, performing an action.

A control unit controls a transfer machine to execute: a first article delivery operation to store a target article in a first placement region as a first article; and a second article position adjustment operation of moving a second locking member disposed between the first article and a second article in a depth direction toward a depth-direction far side to a position corresponding to a position of a front surface portion of the second article located at a second article proper position, and the control unit is configured to, after the target article has been stored in the first placement region as the first article, cause the transfer machine to execute the second article position adjustment operation, and, upon end of the second article position adjustment operation, cause a first locking member be restored to a position corresponding to a holding region to end the first article delivery operation.

A remotely operated vehicle assembly for picking up storage bins from a storage system includes a vehicle body that displays a cavity for receiving a storage bin situated somewhere within the storage system, a vehicle lifting device at least indirectly connected to the vehicle body for lifting the storage bin into the cavity, driving mechanisms or components connected to the vehicle body allowing remotely controlled movements of the vehicle assembly within the storage system, a wireless communication link that provides wireless communication between the vehicle assembly and a remote control unit such as a computer, one or more main power sources supplying electrical power to the driving mechanisms or components and vehicle coupling means for operational and releasable coupling of the main power source to the vehicle body.

System includes an article supply location that 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 one or more removal devices that transport the container to a location of further processing. System further includes a control system 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, deposit the article in the destination container, and transport the destination container to a location for further processing by manipulation of the removal device.

An automated storage and retrieval system includes a storage grid provided by a framework structure arranged in a building under a ceiling. The framework structure includes a rail system arranged at an upper level of the framework structure. The rail system includes a first set of parallel rails arranged in a horizontal plane and extending in a first direction, and a second set of parallel rails arranged in the horizontal plane and extending in a second direction which is orthogonal to the first direction. The first and second sets of rails form a grid pattern in the horizontal plane including a plurality of adjacent access openings/grid cells. The storage grid defines a plurality of storage columns. Each storage column being arranged to store a respective stack of storage containers. The storage columns are located beneath the rail system. Each storage column is located vertically below a respective access opening/grid cell. Container handling vehicles operate on the rail system to collect and return storage containers to and from storage columns. A control system monitors and controls the automated grid storage and retrieval system. A method for monitoring the automated storage and retrieval system includes: launching a flying drone equipped with a camera to an altitude in an airspace located between an upper surface of framework structure and the ceiling or roof obstacle beneath the ceiling, navigating the drone to a suspected location of an anomaly in the system or other aspect of the system in need of inspection, using the drone to locate the anomaly or aspect of the system in need of inspection, and performing a visual inspection of the anomaly or aspect of the system in need of inspection using the camera of the flying drone. The control system includes an exception handler module responsible for identifying and attempting to correct anomalies in the operation of the storage system, and a flight control module responsible for controlling the flight of the drone. The flight control module directs the flight of the drone in response to instructions received from the exception handler module.