An inventory container diverter system is described. The system includes a conveyor to move totes through a shipment processing area and a redirection device to push totes perpendicularly off the conveyor at predetermined locations. Adjacent the redirection device is a chute which the tote slides down to present the tote to a user at an easily accessible height and tilted at such an angle to enable simple and efficient access to the interior of the tote. The chute includes a door to help prevent totes from falling out of the chute. A tote sensor detects when the chute is occupied by a tote or when it is clear and a door sensor detects when the door of the chute is closed. When the door is closed and the chute is clear the system directs a new tote to the redirection device and pushes it into the chute.

A waste disposal system for the disposal of consumables through a waste chute into a waste container includes a waste chute having a first opening and a second opening, wherein the first opening is situated outside the waste container and the second opening opens toward the waste container. The first opening and the second opening are arranged at a first distance from one another, wherein the waste chute includes a plurality of self-resetting lamellae for the partial or complete closure of the openings. The lamellae form at least two lamella annuli arranged at a second distance above one another, wherein at least one first lamella annulus closes the first opening and at least one second lamella annulus closes the second opening, and the second distance between the lamella annuli is at least one third, preferably at least half and particularly preferably at least three quarters of the first distance.

A conveyor system for conveying goods having a lying conveyor for conveying the goods horizontally, where the lying conveyor includes a sorting device with multiple delivery points, and having an overhead conveyor, by way of which the goods are conveyed in a suspended manner on a goods carrier, where the overhead conveyor is connected to at least one of the delivery points for delivering the goods.

A component supply device includes a storage section, a mounting section, and a component support section. The storage section stores multiple components. The storage section is mounted to the mounting section. The storage section is attachable and detachable in relation to the mounting section. The component support section supports, in a scattered state, multiple components which are discharged from an opening of the storage section which is in a state of being mounted to the mounting section.

A system, and associated method, for launching and delivering separated food product in organized groups to a robotized packaging station for the product. The system initiates the delivery via a metered hopper of food product delivering the product to a launch V-belt that aligns the product end to end. A successive singulator belt, positioned adjacent to and receiving product from the launch belt, further organizes the product into a single file alignment. An optional separator belt may follow the singulator belt to create gaps between successive product units. The product is then delivered to a pick belt for product to be provided to the packaging robot. The system product information is from a single (per product delivery line) sensor, enabling intergrated end-to-end control from hopper to robot, and a nearly continuous motion of said pick belt.

Systems, methods, and computer-readable media are disclosed for automated item sortation and container handling. In one embodiment, an example method may include determining, by a controller, a first item identifier of a first item at an induction portion of a sortation system, determining an order identifier associated with the first item identifier, and determining a first container associated with the order identifier. The method may include causing a first mobile carrier unit to receive the item, and causing the first mobile carrier unit to deliver the first item to the first container.

A method includes: storing (i) a reference image of a chute for receiving objects, and (ii) a region of interest mask corresponding to a location of the chute in a field of view of an image sensor; at a processor, controlling the image sensor to capture an image of the chute; applying an illumination adjustment to the image; selecting, at the processor, a portion of the image according to the region of interest mask; generating a detection image based on a comparison of the selected portion and the reference image; determining, based on the detection image, a fullness indicator for the chute; and providing the fullness indicator to notification system.

Provided are a parcel sorting system and method. The parcel sorting system is arranged in layers and includes: a parcel sorting layer (10) located on an upper layer of the parcel sorting system, a moveable container carrying layer (11) located on a lower layer of the parcel sorting system, a parcel delivery robot (12) and a control device (13). The parcel sorting layer (10) includes a modular entity platform (101) is a physical platform formed by splicing multiple splicable units and used for sorting parcels. The modular entity platform (101) includes multiple delivery lattices (1011) arranged in an array and a traveling area constituted by gaps between the multiple delivery lattices (1011) and used for the parcel delivery robot (12) traveling. One delivery lattices (1011) corresponds to one or more delivery path directions. The moveable container carrying layer (11) includes multiple moveable containers (110), and a part of the movable containers are located below the multiple delivery lattices (1011) and receive the parcel from the parcel sorting layer (10).

A system, and associated method, for launching and delivering separated food product in organized groups to a robotized packaging station for the product. The system initiates the delivery via a metered hopper of food product delivering the product to a launch V-belt that aligns the product end to end. A successive singulator belt, positioned adjacent to and receiving product from the launch belt, further organizes the product into a single file alignment. An optional separator belt may follow the singulator belt to create gaps between successive product units. The product is then delivered to a pick belt for product to be provided to the packaging robot. The system product information is from a single (per product delivery line) sensor, enabling integrated end-to-end control from hopper to robot, and a nearly continuous motion of said pick belt.

A sorting system includes one or a plurality of transporter units, at least one loading station for loading a parcel onto transporter units, a plurality of destination stations, and a network of paths, each path including at least one track, the network including a plurality of junctions where at least two of the paths intersect. Each transporter unit is controllable to travel along the paths of the network of paths and to continue travelling along one of the at least two paths at a junction. A controller is configured to calculate a route within the network of paths between a loading station and a selected destination station, and to control the transporter unit to travel along the calculated route.