A racking system and components are provided in which multiple storage positions are provided for individual storage boxes and automated guided vehicles are present to carry out automated placement, relocation and retrieval of boxes from storage positions in which they are located. The racking system has horizontally extending storage layers in each of which multiple storage positions are located and alternating vertically juxtaposed transfer layers in which automated guided vehicles are movable in at least two directions that are at right angles to each other to place, relocate and retrieve boxes to and from storage positions by vertical movement of the boxes into and out of storage positions in storage layers located above or below a transfer layer. The storage positions have associated with them storage guides for guiding boxes into and out of the storage positions and support arrangements for supporting the boxes in their storage positions.

Systems 1000, methods, and machine-executable coded instruction sets for the fully- and/or partly automated handling of goods. In particular, the disclosure provides improvements in the storage and retrieval of storage and delivery containers in order processing systems.

A robotic storage assembly includes a safe that may a plurality of items. A drawer is slidably coupled to the safe. A control is coupled to the safe and the control may be manipulated. A storage unit is positioned within the safe to contain the plurality of items. The storage unit includes a plurality of trays. A spacing unit is positioned within the safe and the spacing unit engages the plurality of trays. The spacing unit selectively spaces the trays apart from each other. A retrieval unit is positioned within the safe. The retrieval unit is selectively positioned between the trays when the trays are spaced apart. Thus, the retrieval unit retrieves the items in the storage unit. The retrieval unit is selectively aligned with the drawer to deposit the items in the drawer. Thus, the items may be removed from the safe.

The present disclosure relates to stacked, grid storage systems such as densely packed storage systems, and methods of adjusting, regulating, controlling and maintaining the temperature of storage systems.

A loading apparatus for loading food products onto and/or into a slicing apparatus, in particular a high-speed slicer, comprises at least one magazine unit that includes a conveying means that endlessly circulates along a running direction. The conveying means is configured to lift the products to a transferring height at which the products can be transferred to the slicing apparatus and includes several product support surfaces, the product support surfaces being oriented essentially perpendicular to the running direction and positioned subsequently along the running direction with a space between each other. At least one product is loadable onto a respective product support surface for lifting the product to the transferring height.

A workstation for a material handling system is provided. The system may include a plurality of vehicles for retrieving items from a plurality of storage locations located in one or more racks. The workstation is configured to accommodate the vehicles so that the vehicles drive into the workstation and drive upwardly along a track in the workstation. In one configuration, the track is configured to tilt the vehicle at a predetermined angle relative to the horizon as the vehicle is driven upwardly. After the vehicle is tilted to the predetermined angle the vehicle continues to drive upwardly while maintaining the predetermined angle.

An overhead guide track system for automated material handling and storage facilities wherein at least one transfer unit is suspended from carriages that travel along the track system, the track system including a plurality of first and second support beams being assembled in an X-Y manner such that the first and second support beams intersect with one another in perpendicular relationship and wherein each of the first and second support beams includes a horizontal flange connected to a central vertical web, each of the vertical webs of the first and second beams having opposite ends connected to vertically oriented pedestals at a plurality of intersections of the first and second support beams and which pedestals support transfer plates over which the carriages are supported as the carriages pass over open gaps between the horizontal flanges at the intersections of the first and second support beams.

An automated storage system includes a three-dimensional storage grid for storing storage containers, at least one container handling vehicle operating on, around or under the storage grid, and a central communication system with a system transmitter and a system receiver for controlling and communicating with the at least one container handling vehicle for handling storage containers in the storage grid. At least one container handling vehicle includes a vehicle communication system with a vehicle transmitter and a vehicle receiver for communication with the central communication system. The system and vehicle transmitters and receivers are configured to use light for wireless communication. The system transmitter and the system receiver are located in the automated storage system on, around, or under the storage grid transmitting the same communication from all the transmitters of the central communication system.

A temporary storage system has a large capacity and loads and unloads articles promptly. The temporary storage system includes a grid-shaped travelling rail and buffers over processing equipment except for an area over a load port, and local vehicles travel along the rail. The carriage of the local vehicles is provided with at least a longitudinal travelling unit, at least a lateral travelling unit, and at least an advancement and retraction mechanism selectively advancing one of the longitudinal travelling unit and the lateral travelling unit to a position supported by the travelling rail, and travels along the travelling rail longitudinally and laterally, and the transfer unit of the local vehicles is provided with a hoist and an arm moving the hoist horizontally. The local vehicles stop at a position corresponding to the load port, advances the arm towards the load port, and transfers an article between the load port.

A displacement mechanism for a remotely operated vehicle includes a motor configured to actuate a drive crank, a coupler link connected to the drive crank on a first side, and a lift rocker on a second side, a displacement link connected to the lift rocker, and a displacement plate connected to the displacement link and having a plurality of wheels provided thereon. The drive crank, the coupler link, the lift rocker, the displacement link, and the displacement plate are each respectively connected with pivot connections such that actuation of the motor actuates the displacement plate between a raised position and a lowered position. The lift rocker is configured with a pivot point arranged in a body of the lift rocker such that the lift rocker, the pivot connection between the displacement link and the lift rocker, and the pivot connection between the lift rocker and the coupler link each rotate around the pivot point when the motor is actuated.