An autonomous transport vehicle including a frame forming a payload area, telescoping arms movably mounted to the frame, each telescoping arm being configured for extension and retraction relative to the frame along an extension axis to effect transfer of at least one pickface to and from the payload area, and traversal, relative to the frame, in at least one direction that is angled to the extension axis, and at least one tab extending from each telescoping arm where the at least one tab extends in a direction transverse to the direction of extension and retraction, and the at least one tab on one of the telescoping arms opposes the at least one tab on another of the telescoping arms.

Method for securing a first and a second upright, including the following steps of a) attaching the connectors and b) adjusting the position of the first upright and the position of the second upright such that the first lower end of a first climbing element and the second lower end of second climbing element lie in a plane substantially orthogonal to a climbing direction.

A controller for a commissioning device for storing piece goods such as medicinal packages is provided. The controller includes a delivery table that extends in a first direction, two elongated clamping jaws disposed above the delivery table, the jaws having clamping surfaces that face one another, and a clamping jaw guide apparatus with a frame structure, at least one first and one second guide which are separated from one another in the first direction and extend in a second direction, and at least four clamping jaw carriages which are coupled to the guides and driven in the second direction. Two clamping jaw carriages each are associated with a guide and at least two clamping jaw carriages separated from one another in the first direction are coupled to one clamping jaw, respectively.

A hybrid modular storage fetching system is described. In an example implementation, an automated guided vehicle of the hybrid modular storage fetching system includes a drive unit that provides motive force to propel the automated guided vehicle within an operating environment. The automated guided vehicle may also include a container handling mechanism including an extender and a carrying surface, the container handling mechanism having three or more degrees of freedom to move the carrying surface along three or more axes. The container handling mechanism may retrieve an item from a first target shelving unit using the carrying surface and the three or more degrees of freedom and place the item on a second target shelving unit. The automated guided vehicle may also include a power source coupled to provide power to the drive unit and the container handling mechanism.

Various embodiments relate to magnetically moveable displacement devices or robotic devices. Particular embodiments provide systems and corresponding methods for magnetically moving multiple movable robots relative to one or more working surfaces of respective one or more work bodies, and for moving robots between the one or more work bodies via transfer devices. Robots can carry one or more objects among different locations, manipulate carried objects, and/or interact with their surroundings for particular functionality including but not limited to assembly, packaging, inspection, 3D printing, test, laboratory automation, etc. A mechanical link may be mounted on planar motion units such as said robots.

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.

Apparatuses, methods and systems for dynamically retrieving objects are disclosed herein. In one example, a retrieval apparatus is provided. The example retrieval apparatus comprises: at least one moveable arm mechanism configured to engage a surface of at least one of a plurality of objects; at least one sensing element configured to obtain sensor data describing locations and characteristics of the plurality of objects as the retrieval apparatus traverses an environment associated with the plurality of objects; and a controller component in electronic communication with the at least one arm mechanism and the at least one sensing element, wherein the controller component is configured to modify operational data based at least in part on the sensor data.

A storage, retrieval and processing system for processing objects includes: a plurality of bins including objects to be distributed, said plurality of bins being provided on an input conveyance system; a programmable motion device that includes an end effector for grasping and moving any of the objects, a perception system for providing perception data regarding a selected object that is presented to the perception system by the programmable motion device, and a routing conveyance system for receiving the selected object, and for moving the selected object in each of horizontal and vertical directions toward a selected destination container responsive to the perception data, the routing conveyance system including at least one object conveyor for urging the selected object toward the selected destination container in a third direction that is generally orthogonal to the horizontal and vertical directions.

A transport vehicle (2) that travels along a container shelf (1) is provided with a plurality of levels of shelf portions (11) arranged in a vertical direction (Z) and configured to support containers (W), thereby transporting the containers (W). The transport vehicle (2) is provided with a support region where a container (W) is supported, a first transfer apparatus (23) that inserts/takes the container (W) into/out of the container shelf (1), and a second transfer apparatus (24) that loads/unloads the container (W) on/from the support region. The second transfer apparatus (24) is configured such that a container (W) can be moved to the support region so as to allow a plurality of the containers (W) to be supported in a stacked state in the support region.

A self-locking assembly includes one or more shelves. Each of the shelves has dividers, which define storage bays that are adjacent to each other in a lateral direction and adjacent storage bays being spaced apart from each other by one of the dividers positioned therebetween, and a lock contained within each storage bay. The self-locking assembly also includes one or more storage units having a width that is a same as, or smaller than, a width of at least one of the storage bays. Each of the storage units has an upper surface, which transports item(s) supported thereon, and an interlocking feature that engages with the lock of one of the storage bays to resist removal of each storage unit from a corresponding one of the storage bays. Each storage unit can be inserted into and removed from a corresponding one of the storage bays in a longitudinal direction.