A system may include a vehicle for delivering items and a moveable track that cooperates with the vehicle. The moveable track may cooperate with a storage system having storage locations for storing items. The vehicle may drive into the moveable track and lift the track using a vertical drive mechanism. The vehicle may include a horizontal drive system operable to drive the vehicle horizontally along the ground to carry the moveable track to a position adjacent the storage location. The vehicle may operate the vertical drive system to drop the moveable track adjacent the storage system. Additionally, the vehicle may operate the vertical drive to drive up the moveable track to an elevated position adjacent one of the storage locations in the storage system. The vehicle may include a transfer mechanism for transferring items between the vehicle and the storage location while the vehicle is in the elevated position.

The present invention relates to the technical field of vertical automatic storage cabinets and provides a vertical automatic storage cabinet that comprises: a cabinet body; storage racks; a grasping structure and a conveying structure. In the present vertical automatic storage cabinet, at least two storage racks are provided to be spaced apart in the height direction of the cabinet body, and the grasping structure is located in the area between the two storage racks. When in use, the storage boxes on both the upper and lower sides can be taken off the mounting rack, then can be transferred to the conveying structure, and the storage boxes can be conveyed to the outside of the cabinet body.

An autonomous transport vehicle for transferring case units to and from predefined storage areas in an automated case unit storage system, the automated case unit storage system including an array of multilevel storage racks with picking aisles passing therebetween and at least one multilevel vertical conveyor having movable shelves, the autonomous transport vehicle including a frame configured to traverse the picking aisles and a transfer deck connecting the picking aisles to the at least one multilevel vertical conveyor for transferring case units between the predefined storage areas and the at least one multilevel vertical conveyor, and a controller connected to the frame, the controller being configured to effect movement of the autonomous transport vehicle through the picking aisles for accessing each storage area within a respective level of the array of multilevel storage racks and each shelf of the at least one multilevel vertical conveyor.

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 path to/from the destination areas, which are positioned along the path. Once at the appropriate destination area, an item is transferred between the delivery vehicle and the destination area.

An automated carrier system is disclosed for moving objects to be processed. The automated carrier system includes a discontinuous plurality of track sections on which an automated carrier may be directed to move, and the automated carrier includes a base structure on which an object may be supported, and at least two wheels assemblies being pivotally supported on the base structure for pivoting movement from a first position to a second position to effect a change in direction of movement of the carrier.

A load handling device for lifting and moving one or more containers stacked in a storage system with a grid framework structure supporting a plurality of tracks arranged in a grid pattern to define a grid structure above the one or more stacks of containers, the load handling device including: A) a driving mechanism; B) a vehicle body housing: i) a container receiving space located above the tracks; ii) a lifting device having a lifting drive assembly and a grabber; and iii) a cassette housing a rechargeable power source for powering the driving mechanism; wherein a thermal management system includes a temperature sensor and at least one temperature regulating device configured to maintain the temperature of the rechargeable power source.

Apparatuses, systems, and methods for providing dynamic control in an automated storage and retrieval system (ASRS) are provided. For example, an example method may include retrieving throughput data associated with an ASRS, wherein the throughput data comprises at least one of an expected throughput rate or an actual throughput rate associated with the ASRS; retrieving at least one throughput range associated with the ASRS, wherein each of the at least one throughput range comprises an upper throughput limit associated with the ASRS and a lower throughput limit associated with the ASRS; and adjusting at least one speed setting of at least one article transport device of the ASRS based at least in part on the throughput data and the at least one throughput range.

The invention concerns an automated storage and retrieval system, a storage container handling vehicle and a method for operating such a system. The system comprises a plurality of vehicles, where each vehicle comprises a vehicle body (30), a thereto connected wheel assembly configured to guide the vehicle along the track system, a container picking device (4) for releasably attaching to a storage container, comprising one or more pivot arms (5) having a first end pivotally connected to the vehicle body at pivot point (PP). The configuration of the container picking device is such that it is movable in a pivoting motion of the pivot arm about the pivot point between a first, lifting position enabling the container picking device to lift at least one storage container from a position outside the horizontal extent of the vehicle body and a second, transport position enabling the container picking device to hold the at least one storage container at least partly inside the horizontal extent of the vehicle body.

A system and method for operating robotic pallet transportation carts and providing uniform spacing between pallets of goods, to improve the vertical alignment of the gaps between the pallets of a multilevel commercial warehouse rack. Indicators are positioned along a storage lane, such as on side walls of cart support rail structures, on the left and/or right sides with respect to the pallet transportation cart. The cart has one or more sensors (optical, magnetic and otherwise), such as on a side of the cart to detect the indicators on the side of the lane. The cart is programmed to count the indicators and lower the pallet of goods after sensing a selected indicator number. By spacing the indicators an appropriate distance apart, the pallets can be arranged to have vertically aligned gaps, even if there are minor variations in the length of pallets of goods.

A load handling device is disclosed for lifting and moving storage containers stacked in a grid framework structure having first and second sets of parallel rails or tracks. The load handling device includes: a body mounted on first and second sets of wheels arranged to engage with the tracks. A direction-change assembly is arranged to raise or lower the first set of wheels and or lower or raise the second set of wheels with respect to the body to engage and disengage the wheels with the tracks. The direction-change assembly includes a linkage-set having a series of members arranged between a traveller and a fixed brace, wherein the traveller is arranged to move under an applied force to cause the wheels to raise or lower.