This application relates to the technical field of intelligent logistics, and discloses an intelligent sorting system and method, a warehouse robot, and a processing terminal. The system includes a warehouse robot. The warehouse robot includes a box storage unit and a handling assembly. The warehouse robot may receive a box replacement instruction, where the box replacement instruction includes information of a to-be-replaced first box, and instruct, according to the box replacement instruction, the handling assembly to replace the first box with a second box stored in the box storage unit. Therefore, box replacement is realized by a robot. In this way, the efficiency of cargo sorting is enhanced.

The present invention relates to a parcel sorting system which is operated using two separate tracks so as to distinguish between concentrated population areas and other areas, and feed and sort only parcels destined for a corresponding area, whereby parcel sorting can be efficiently performed, and the system can be efficiently constructed while occupying a small area.

An arrangement position determination method of an object, including: based on information of dimensions of a predetermined area and dimensions of a plurality of objects to be accommodated in the predetermined area stored in a storage section of a control device, searching for a position at which the object does not interfere with a boundary of the predetermined area and other objects in a first direction; and when there is no position at which the object does not interfere with the boundary and the other objects in the first direction, searching for a position at which the object does not interfere with the boundary and the other objects in the first direction at a position shifted in a second direction orthogonal to the first direction.

A method and computer program product controls the transferring of a storage container for storing items by transferring the storage container via access station at an interaction area among a plurality of interaction areas of an automated storage and retrieval system. The storage container is linked to a user and items stored. The method performed by the computer program product includes specific modules performing different steps of the method. The modules include a user identification module processing user identification data and giving access to the system, a registration module registering items to be stored in an inventory database, a search module for searching for stored items in the inventory database, a presentation module presenting search results and items stored, and an execution module generating instructions that via a communication module is instructing a system controller of the automated storage and retrieval system to retrieve or store a specific storage container.

The vending machine control system S performs authentication processing for authenticating a user on the basis of information on the user who is about to open a door 13 of a vending machine 1, and when the user is authenticated, performs control to unlock the door 13 of the vending machine 1. Then, the vending machine control system S identifies a product picked up from a storing chamber 12 after the door 13 is unlocked, and when a reserved product is included in the identified product, outputs different information depending on whether or not the authenticated user is a reservation person of the reserved product.

A box handling system is disclosed for use in an object processing system. The box handling system includes a box tray including a recessed area for receiving a box, and the recessed area includes a plurality of floor and edge portions for receiving the box that contains objects to be processed.

An enhanced shipping container apparatus that maintains packages is described having integrated fire suppression. The apparatus has a container base supporting the packages, multiple container walls coupled to the container base, and a container top coupled to each of the container walls. A fire suppression panel is integrated as part of one or more of the walls and top portion, and has a support sheet of fire resistant material; an interior exposed sheet of temperature sensitive material; a sealed boundary connecting the support sheet and interior exposed sheet on peripheral edges (where the sealed boundary, support sheet and interior exposed sheet define a holding cavity), and integrated fire suppression material in the holding cavity. The temperature sensitive material of the interior exposed sheet releases the integrated fire suppressant material from within the holding cavity when the temperature sensitive material of the interior exposed sheet is exposed to a threshold temperature.

Systems, methods, and computer-readable media are disclosed for directed palletization using lights. In one embodiment, an example system may include a conveyor configured to support packages, a first set of LEDs disposed along a first side of the conveyor, the first set of LEDs having a first LED, a second set of LEDs disposed adjacent to the first set of LEDs, the second set of LEDs having a second LED, and a first sensor configured to identify packages. The system may include a second sensor disposed on the first side of the conveyor, and a third sensor disposed on the first side of the conveyor. A first color of the first LED may indicate the first package is to be scanned at the second sensor, and a second color of the second LED may indicate the second package is to be scanned at the third sensor.

It is discloses a device and method for controlling a material flow (18) in a storage and picking system (10) at a sensor-controlled node (12) of the material flow (18), where a decision on a future direction of material flow or on a velocity of the material flow (18) is to be taken, wherein at least an inlet section (28) of the node (12) is detected by a, preferably single, sensor (22), comprising the steps of: by means of the sensor (22) generating (S10) sensor data (46) representing the material flow (18) which is defined by one or more material-flow objects (36), approaching the node (12) in a downstream direction, in a field of vision (26) of the sensor (22), in particular in an inlet section (28) of the node (12); checking (S16) whether the sensor data (46) includes for each of the approaching objects (36-1, 36-2) at least one associated object feature (40) allowing certain identification of the corresponding object (36); and, if the sensor data (46) includes for each of the objects (36-1, 36-2) the at least one associated feature (40) allowing the certain identification, controlling (S18) the material flow (18) at the node (12) based on the sensor data (46); or, if the sensor data (46) does not include for each of the approaching objects (36-1, 36-2) the at least one associated feature (40) allowing the certain identification (S16), controlling (S26) the material flow (18) at the node (12) at least for such of the objects (36-1, 36-2), the associated feature (40) of which is not included in the sensor data (46), based on an information fusion (S22) of the sensor data (46) with pre-generated additional data (50), which originates from at least one information source (52) which differs from the sensor (22) of the node (12), wherein the additional data (50) includes additional object features (40) which allow, together with the features (40) from the sensor data (46), a sufficiently certain identification (S24).

An object processing system is disclosed that includes a plurality of track sections, and a plurality of remotely actuatable carriers for controlled movement along at least portions of the plurality of track sections, wherein each of the remotely controllable carriers is adapted to support and transport an object processing bin.