The application relates to a carrying robot including a fork. The fork includes a telescopic arm and a temporary storage tray. The telescopic arm includes a fixed arm and a movable arm connected to the fixed arm. The movable arm is telescopically movable relative to the fixed arm. The temporary storage tray is mounted to the fixed arm and is configured to temporarily store goods. The temporary storage tray is able to extend relative to the fixed arm. An extending direction of the temporary storage tray is consistent with an extending direction of the movable arm. When the fork pulls in or pushes out the goods, containers can be stably transferred between a stationary rack and the temporary storage tray.

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.

An automated warehouse system and method are provided for controlling the internal microclimate of receptacles within a warehouse or order fulfilment facility. The system provides independent environmental condition monitoring and regulation for each tote. The system enables individual totes to be maintained at adequate or substantially ideal conditions, independent of its position within a storage system or the environmental conditions of adjacent totes in the storage system. The totes may include self-contained environmental control systems and/or the storage system may include environmental control inputs to adjust or maintain the environmental conditions within a particular tote. The system is operable to monitor and control the microclimate of a tote while it is stored at a storage location within the storage system or in a buffer, and may be operable to monitor and/or control the microclimates of the totes while they travel throughout the system.

An automated warehouse system and method for climate controlled storage and order fulfilment comprises a control system, an automated storage and retrieval system (“ASRS”) with a storage rack defining storage locations for storage receptacles for containing goods, where either at least some of the storage receptacles are individually temperature controllable or the storage rack is at least partially disposed in a frozen environment. A transportation system is coupled with the ASRS for transporting storage receptacles to and from the automated storage and retrieval system, and a workstation is in communication with the transportation system for picking goods to a temperature-controlled order receptacle. The control system directs order fulfilment operations comprising directing goods requiring stable temperature control from the ASRS to the workstation and directs an operator to pick the goods from the storage receptacle to the temperature-controlled order receptacle to maintain the goods within a required temperature range.

A racking for storing articles having guiding tracks and a rail vehicle, which may be moved on the guiding tracks for storing and retrieving the articles, wherein the guiding tracks merge in an intersection area. Within the guiding tracks there are formed current bars and at the rail vehicle there are formed current receivers engaging with the current bars and supplying the rail vehicle in the guiding tracks with energy. The intersection area is free of current bars. The rail vehicle has an intersection sensor, which is configured to detect whether the rail vehicle is within the intersection area. The vehicle control is configured to switch the rail vehicle, on the basis of the signals of the intersection sensor and the voltage in the guiding tracks, into different operation modes.

A system for replenishing a self-service pick-up cabinet, a self-service pick-up cabinet system, an apparatus, and a method are provided. The system for replenishing self-service pick-up cabinet controls, by means of a control system, an goods transport device to acquire replenishing goods at an inlet of a self-service pick-up cabinet, and transports the replenishing goods to a goods locker, which is designated by the control system, of the self-service pick-up cabinet. The self-service pick-up cabinet system comprises the system for replenishing a self-service pick-up cabinet, the self-service pick-up cabinet and an unmanned delivery vehicle. The unmanned delivery vehicle transports and unload the replenishing goods to the inlet of the self-service pick-up cabinet. The replenishing efficiency of the self-service pick-up cabinet is improved and the labor cost is reduced.

A method for retrieving an inventory item based on a handling robot, where the handling robot includes: a storage frame; and a material handling device installed on the storage frame, and including a telescopic arm and a manipulator installed to the telescopic arm; and the method for retrieving an inventory item includes: driving, by the telescopic arm, the manipulator to extend to a preset position of warehouse shelf along a preset horizontal reference line; loading, by the manipulator that is remained on the reference line, the inventory item located in the preset position; driving, by the telescopic arm, the manipulator loaded with the inventory item to move to the storage frame along the reference line; and unloading, by the manipulator that is remained on the reference line, the inventory item to the storage frame.

A remotely operated vehicle assembly for an automated storage and retrieval system moves a product item between a storage container stored in an automated storage and retrieval grid configured to store a plurality of stacks of storage containers, and target containers. The remotely operated vehicle assembly includes a first vehicle including a vehicle body and a wheel arrangement connected to the vehicle body configured to move the remotely operated vehicle along a rail system of the automated storage and retrieval system; and a picking system for moving the product item. The first vehicle includes a container lifting device configured to carry a first target container. The vehicle assembly further includes a second vehicle including a vehicle body and a wheel arrangement connected to the vehicle body configured to move the remotely operated vehicle along a rail system of the automated storage and retrieval system. The second vehicle includes a container lifting device configured to carry a second target container. A bar system mechanically connects the vehicles of the vehicle assembly to each other. The picking system is connected to the bar system. The picking system is configured to move the product item from the storage container to one of the first or second target container.

A method and apparatus are provided for sorting or retrieving items to/from a plurality of destinations areas. The items are loaded onto one of a plurality of independently controlled delivery vehicles. The delivery vehicles follow a track that guides the delivery vehicles to/from the destination areas, which are positioned along the track. Once at the appropriate destination area, an item is transferred between the delivery vehicle and the destination area.

A system for movement of products is described. The system uses a facility which contains warehouse shelves, each shelf includes various devices to move products within the shelf. Some rollers on the shelf are active, others passive. Power is transferred to the active rollers from an end of arm tool.