A temporary storage shelf board, a goods shelf, a control method, an apparatus and a system are provided. The temporary storage shelf board is used for providing multiple temporary storage positions. The temporary storage shelf board is provided with fork pockets, and the fork pockets is used for cooperating with a fork arm of a first robot. A goods storage and retrieval channel of the first robot is formed below the temporary storage shelf board, and when goods are stored and retrieved, the first robot is located at the goods storage and retrieval channel, and the fork pockets cooperate with the fork arm on the first robot to store and retrieve the goods. Thus, the efficiency of goods storage and retrieval can be improved.

A handling robot used in a field of warehouse logistics comprises a mobile chassis, and a storage shelf. The storage shelf is mounted to the mobile chassis and comprises a plurality of layered plate components distributed at different heights. The handling robot further comprises a handling device configured to transport a material to a layered plate of the plurality of layered plate components, and a lift component configured to drive the handling device to lift relative to the storage shelf.

A warehousing system including a shelving unit, a goods-container-moving device, and a control terminal. The shelving unit is provided with a plurality of storage spaces configured to place a storage-goods container or a collection-goods container, wherein the storage-goods container is configured to store goods; the control terminal is configured to send a first control instruction to the goods-container-moving device; the goods-container-moving device is configured to move a target storage-goods container storing target goods to a first picking area; the control terminal is further configured to obtain a free storage space on the shelving unit, and send a second control instruction to the goods-container-moving device; and the goods-container-moving device is further configured to temporarily store the collection-goods container that completes the picking of the target goods to the free storage space.

Provided are systems, methods, and devices for storing and transporting articles with a multi-shelf storage unit. A system for article handling includes a multi-shelf storage unit and a robotic unit. The multi-shelf storage unit includes a plurality of shelves disposed on a frame, the plurality of shelves including at least one vertically moveable shelf configured to move in first and second vertical directions relative to the frame, and a lift mechanism configured to automatically drive, in response to receiving a drive input, the at least one vertically moveable shelf in the first or second vertical direction. The robotic unit includes an end effector disposed on a robotic manipulator for engaging an article and a lift mechanism actuator that is connectable to the lift mechanism and configured to provide the drive input to actuate the lift mechanism.

Disclosed is an automatic transport device, comprising: a distance sensor for measuring the distance between a surrounding object and the automatic transport device; a movable chassis provided with a power wheel for driving the automatic transport device; a bearing part provided with a space for bearing a container; a container sensor for sensing whether the container is associated with the automatic transport device; a wireless communication module for transmitting the serial number of the container to a remote server after it is determined that the container is associated with the automatic transport device, and receiving picking information that has been fed back; and a display screen for displaying the serial number of the associated container and the picking information. Further disclosed is a picking information acquisition and display method.

A parent tote container is segmented into smaller, child tote containers. Each of the child tote containers includes products that are commonly sold together and are removed from the tote containers at picker stations with the same type of picker mechanism. Items are moved from the child tote containers to a customer order tote container at a picker station.

A lift system for an automated storage system of the type where storage containers are stacked in storage columns arranged in a grid, and where automated container handling vehicles retrieve and replace containers from a top level of the grid. The lift system has a platform vertically movable adjacent to a face of the grid, arranged for receiving and transporting one or more containers. A dedicated mechanical device is arranged for grabbing, lifting and moving the storage containers from a staging area at the top of the grid and placing containers on the platform and vice versa.

A system for unloading parcels from a cargo area includes: an extendible conveyor; a transfer conveyor for conveying parcels to the extendible conveyor; and a mobile robot assembly configured to engage and transfer parcels in the cargo area onto the transfer conveyor. The mobile robot assembly repeatedly advances and transfers parcels in the cargo area to the transfer conveyor. As the mobile robot assembly advances within the cargo area, the transfer conveyor and the extendible conveyor follow to provide a pathway along which parcels transferred by the mobile robot assembly can be transferred out of the cargo area. The mobile robot assembly includes: a mobile base for repositioning the mobile robot assembly; a framework mounted to the mobile base; a first robot and a second robot, each mounted for vertical movement with respect to the framework and configured to engage and transfer parcels; and a vision and control subsystem.

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, for moving the vehicle along a first direction on a rail system in the grid; and a second set of wheels, for moving the vehicle along a second direction on the rail system in the grid, the second direction being perpendicular to the first direction. A vehicle body includes walls on all sides and forms a quadrilateral footprint. The footprint is defined by horizontal peripheries in the first and second directions of the vehicle body. The container handling vehicle further includes a first section and a second section arranged side-by-side such that a centre point of a footprint of the first section is arranged off centre relative a centre point of the footprint formed by the vehicle body. The first and second sections are separated by a divider element. The first set of wheels includes two pairs of wheels, including a first and third wheel and a second and fourth wheel, respectively, arranged on opposite portions of the first section, wherein the first and third wheel of the first set of wheels are connected to the vehicle body and the second and the fourth wheel of the first set of wheels are connected to the divider element. The second set of wheels includes two pairs of wheels, including a first and third wheel and a second and fourth wheel, respectively, arranged on opposite portions of the vehicle body. Two of the wheels in the second set of wheels are arranged on opposite sides of the second section and the other two wheels in the second set of wheels are arranged on opposite sides of the first section. A size ratio of a footprint of the first section relative a footprint of the second section is at least 2:1. The first section is configured to accommodate a storage container, and the second section comprises at least a first battery.

A proximity-detection and speed-control system for a materials-handling vehicle, such as a lift truck, is provided with a recommended direction of travel for the vehicle. A proximity sensor is provided to determine the vehicle's proximity to a restricted member, such as another vehicle, a high-value object, a dangerous location, or a pedestrian. If the vehicle is traveling in the recommended direction of travel, the speed control function is disabled. If, however, the vehicle is not travelling in the recommended direction and the proximity sensor indicates the vehicle is within a restricted distance of the restricted member, the speed control function is triggered to restrict the maximum speed of travel of the vehicle and to slow the vehicle if needed.