A stacker crane includes a transporter, a slide fork, first to third sensors, a counter, and a main controller. The transporter moves from a shelf on which an article is supported to an empty shelf. The slide fork is mounted on the lift stage and transfers the article to and from the shelf. The first, second and third sensors recognize an abnormality of the article moved by the movement of the transporter. The counter counts the number of event occurrences. When an abnormality is recognized by the sensor, the main controller reduces a moving speed of the transporter, and when no abnormality is recognized by the sensor upon reduction in the moving speed, the movement of the transporter is continued. When the number of event occurrences reaches a first threshold, the stacker crane is brought into an abnormal-stop state.

Techniques for automatically modulating a physical configuration of a reconfigurable building structure. A reconfigurable building structure may be constructed of physical elements that are movable with respect to one another to facilitate actuating the reconfigurable building structure between a plurality of different physical configurations. The physical configuration of a reconfigurable building structure may be adjusted to accommodate for physical dimensions of an item that is going to be moved into the reconfigurable building structure. For example, a spacing between two shelves may be expanded in response to an order being placed for a large item. In this way, when the item is delivered to a physical address associated with the reconfigurable building structure, various physical characteristics of the reconfigurable building structure may have already been modulated to accept the item.

A storage setup and method for robotic delivery and retrieval of crates from shelving blocks are disclosed. At least one shelving block in the setup comprises non-uniformly spaced apart storage surfaces. The storage surfaces are accessible to lift-robots. A computerized control system is configured to differentiate between storage locations based on which crate sizes from at least two different ranges of crate sizes a storage location can store. The storage may be automatically optimized by routing robots to store crates in storage locations sized in correlation with the size of the crate to be stored.

A logistics warehousing system includes a conveying device, a plurality of delivery containers, and at least one packing station. The conveying device includes an circular conveyor surrounding a central area. The circular conveyor circulates cyclically relative to the central area. The plurality of delivery containers include at least one first delivery container and at least one second delivery container different from the first delivery container. The plurality of delivery containers are placed on the circular conveyor and circulate along a circular track around the central area cyclically as the circular conveyor circulates. One of the packing stations receives one of the plurality of delivery containers from the conveying device.

An inversion mechanism inverts a first container held by a holding mechanism with a first opening directed upward, and directs the first opening downward. A movement mechanism moves the holding mechanism so that the first opening directed downward faces a second opening from above. The opening and closing drive mechanism brings an opening and closing member into the closed state while the holding mechanism is inverted by the inversion mechanism and while the holding mechanism is moved by the movement mechanism, and brings the opening and closing member into the open state in response to the first opening facing the second opening.

A battery transmission system may comprise: a material incoming structure to receive batteries; a first transfer structure to transfer the batteries to a first pallet so as to convey the batteries on a first transmission line, wherein the first transmission line has an unloading position for which at least one second transmission line is provided correspondingly; and a second transfer structure to transfer batteries at the unloading position to a first starting position of the second transmission line so as to transmits, when the number of batteries at the first starting position reaches N, the N batteries to a first termination position of the second transmission line, wherein N≥1.

A sorting device and a method for sorting articles at delivery points are shown, the sorting device having a conveying device comprising transport platforms that are movable along a transport direction for transporting the articles and for delivering the articles to the delivery points, with the transport platforms having a bearing surface for the articles and with at least one transport platform having a first delivery device for vertically delivering the articles from the bearing surface to at least one first delivery point. To provide a sorting device for reliable and careful joint sorting of articles with different transport and delivery requirements, at least one transport platform has a second delivery device for laterally delivering the articles from the bearing surface to at least one second delivery point.

The present invention relates to a system (1) for arranging items in containers comprising a plurality of processing stations (11) for filling removable containers, wherein each of the processing station (11) is able to house a single of the removable containers and comprises a movable tray (211), able to support a respective of the removable containers, moving means of the movable tray (211) with respect to the processing station (11) and a conveyor (111), provided with an entry portion (111′) and with an exit portion (111″) of the items, wherein the conveyor (111) is arranged at a distance from the movable tray (211) such that the exit portion (111″) remains above the opening of a respective of the removable containers, wherein the moving means are able to operate a shaking of the movable tray (211) at least along opposite directions of a predefined axis of shaking to arrange the items in the removable container in a homogeneous way.

A conveyor system includes at least one conveyor table and an awareness flag mechanism. The awareness flag mechanism includes a support rod mounted to the at least one conveyor table and extending outwardly therefrom in a cross-conveying direction. A counterweight assembly includes a support shaft pivotally connected to the support rod. The support shaft has a resiliently flexible portion. Aa counterweight is located at a lower end of the support shaft. Aa flag is located at an opposite, upper end of the support shaft. The counterweight biases the counterweight assembly toward an upright, awareness configuration where the flag is located above a conveying surface of the at least one conveyor table.

A transport device has a position detection portion, a holding portion attached to an arm, a driving portion to drive the holding portion and the arm, and a control portion. A control portion controls the position detection portion and the driving portion to perform, as one cycle, a procedure to detect a position of a parcel, select parcels based on a predetermined condition, and set priority for the selected parcels, and a procedure to refer to a result of the detection, and cause the holding portion to take out one or more parcels from the accumulation portion in accordance with the priority to transport the parcels to a predetermined location, and excludes, from parcels to be taken out, a second parcel that is present within a predetermined distance from a first parcel and has priority lower than the priority of the first parcel, during the one cycle.