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.

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.

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.

An automated system (1) for handling containers is described, comprising a vertically arranged telescopic fork (10) which comprises a fixed base (5) and at least one slider (20, 30) telescopically sliding with respect to the fixed base (5) on a series of rollers (14) which support the at least one slider (20, 30), further comprising thrusting means (21) driven by actuators (22) and configured for thrusting the containers inside a shelving, or for removing them, following the movement of the slider (20, 30) to which they are connected, the automated handling system (1) further comprising a supplying system (15), installed on the slider (30) to electrically supply the actuators (22) of the thrusting means (21), the supplying system (15) comprising energy accumulating means (16) configured to store the electric energy for supplying the electric moto-reducers (22).

A shuttle vehicle is provided for transporting stored goods in a shelving system. The shuttle vehicle comprises a running gear having wheels mounted thereon to move the shuttle vehicle along guide rails of the shelving system. At least one telescopic guide rail is mounted on the running gear such that its direction of travel deviates from that of the guide rails of the shelving system by a predetermined angle greater than zero. The shuttle vehicle further comprises at least one telescopic system having telescope wheels mounted thereon to retract and extend the telescopic system in a plane along at least one telescopic guide rail relative to the running gear. A shelving system is provided which uses the shuttle vehicle.

Containers can be stored, retrieved, or moved in multilevel storage racks of a transfer facility by storage and retrieval units that can travel in aisles extending parallel to respective rows of compartments of storage units of the multilevel storage rack that, for longitudinal side storage of the containers, has a plurality of storage units of a depth corresponding to a container width that are consecutively arranged in rows longitudinally of the containers along one aisle side and are each separated transversely by one aisle. The storage and retrieval units can move back forth in the aisles and have raisable and lowerable telescopic grabs that can be extended and retracted transversely to the aisles for suspending a container. Corners supports in each of the compartments support the containers only at corners of the containers.

A transferring robot is disclosed in the disclosure. The transferring robot includes a movable chassis configured to move along a path among adjacent warehouse storage containers; a temporary storage shelf provided on the movable chassis, the temporary storage shelf being configured to store a target case; a fetching assembly provided on the movable chassis, the fetching assembly being configured to extend or retract horizontally relative to the movable chassis, so as to realize fetching and placing of the target case between the storage containers and the temporary storage shelf, where a direction along which the fetching assembly extends or retracts horizontally is perpendicular to a moving direction. A warehousing and logistics system includes the foregoing transferring robot. The disclosure further discloses a warehousing system and an item transferring method.

An industrial truck includes a main chassis, a transport platform to transport goods, a lifting device to raise and lower the transport platform, and a pushing device with at least one actuatable pushing arm. The pushing device displaces the goods relative to the transport platform.

A variety of vehicle-based and warehouse-based solutions are provided to increase the adaptability, utility, and efficiency of materials handling vehicles in the warehouse environment, such as a materials handling vehicle comprising a picking attachment is secured to a fork carriage assembly and comprising an X-Y-Z-Ψ positioner to engage and disengage a target tote such that movement of the picking attachment along a Z axis by the X-Y-Z-Ψ positioner is independent of movement of the fork carriage assembly along the vertical axis Z′ by the mast assembly and mast assembly control unit. The fork carriage assembly may comprise a mobile storage cart support platform defined by one or more cart lifting forks, and an anti-rock cart engagement mechanism configured to engage a mobile storage cart supported by the cart lifting forks.

A transportation apparatus (30), includes a bracket (31), a telescopic apparatus (32) and a manipulator (33), where the bracket is mounted to a storage shelf (20), the telescopic apparatus is mounted to the bracket, the manipulator is mounted to the telescopic apparatus, and the telescopic apparatus is used for driving the manipulator to move along a horizontal first reference line (S5) or a horizontal second reference line (S6). The manipulator is driven to move on the first reference line and second reference line that are disposed orthogonally, and thereby the manipulator is able to load or unload goods at any position on the first reference line or second reference line, so as to avoid time being wasted on adjusting an angle of a transportation robot (100). The transportation apparatus has a high transportation efficiency.