System includes an article supply location that includes a plurality of articles to be sorted, first and second transport vehicles, each having a first position in which an article is stowed about the vehicle and a second position in which the article is deposited into a proximal container, and one or more removal devices that transport the container to a location of further processing. System further includes a control system configured to receive an order for a plurality of disparate articles, determine one destination container of a plurality of destination containers to direct the transport vehicle to deposit a selected article, direct the first transport vehicle to transport a selected article to the destination container, deposit the article in the destination container, and transport the destination container to a location for further processing by manipulation of the removal device.

An item sorting system (1) includes a moving belt (1a) and one or more sorting units (2). The sorting unit (2) has an enclosure (3) with a work aperture (4), a suction unit (5) with a suction head (6), and a robot arm unit (7) mounted in the enclosure (3) for moving the suction head (6) within a predetermined operating space within the enclosure (3). The enclosure (3) has one or more shell sections (3a) forming a side wall (3b) of the enclosure (3). In a further aspect, the suction unit (5) has a suction head (6) connected to a suction head channel (11), a low pressure source (12a) connected to the suction head channel (11) via a first valve (13), and a control unit (15) connected to the first valve (13) and arranged to actuate the first valve (13) between a suction position and a release position.

Within a sortation center, robotic drives may coordinate to sort packages. In some instances, first robotic drives on a third floor may deposit packages into first chutes that transfer the packages to a second floor. Awaiting second robotic drives on the second floor may receive the packages and may deposit the packages into second chutes that transfer the packages to a first floor. At the first floor, the packages may arrive into a container associated with shipping the packages. Depositing the packages in the first chutes may align the packages with a respective container on the first floor in a first direction and depositing the packages in the second chutes may align the packages with their respective container on the second floor in a second direction.

Systems, methods, and computer-readable media are disclosed for detection of overfilled containers in sortation systems. In one embodiment, an example container capacity detection system for use with an item sortation machine may include a first sensor positioned to detect a remaining capacity of a first container in the item sortation system, and a controller. The controller may be configured to determine, using the first sensor, that the remaining capacity of the first container is less than or equal to a first threshold, and to send a signal.

In one aspect the invention relates to a sorting system (SortS) for sorting processed parts (P) from a workpiece (W), which has been processed by a laser processing machine (L), in particular a laser sheet processing machine, comprising:—A working table (WT) for supporting the workpiece (W) with the processed parts (P), which have been processed by the processing machine (L),—A fleet of interacting legged mobile robots (MR) for sorting the processed parts (P) in a collaborative manner to a target destination.

An article conveying equipment includes: a carrying apparatus, configured to carry one or more articles to be transported; a travelling apparatus, where the travelling apparatus includes at least two driving wheels located at the bottom of the travelling apparatus, the at least two driving wheels are configured to control the travelling apparatus to rotate in a first rotation direction; and a rotation supporting apparatus, which is located between the carrying apparatus and the travelling apparatus and connected to the carrying apparatus and the travelling apparatus respectively, where the rotation supporting apparatus is configured to rotate in a direction opposite to the first rotation direction when the travelling apparatus rotates in the first rotation direction.

An article boxing system includes an image processing apparatus, a first robot, and a first controller. The image processing apparatus detects edges of an article based on an image of the article. The image processing apparatus calculates information relating to a conveyance state. The first robot includes a hand unit and an arm adjusting three-dimensional coordinates and an inclination of the hand unit with respect to a conveyance direction. The first controller controls an operation of the arm to move the hand unit in correspondence with the information relating to the conveyance state and causes the hand unit to adsorb the article, when the article reaches an operation range of the first robot.

An automating seed sorting system is provided comprising a tray subsystem, a de-lidding subsystem, an extraction subsystem, and a collection subsystem. The tray subsystem is configured to remove at least one tray from a cart and, subsequently, return the at least one tray to the cart. The de-lidding subsystem is structured and operable to remove a lid from the at least one tray. The extraction subsystem is configured to extract one or more seeds from the at least one tray and release the one or more seeds into a funnel assembly. And, the collection subsystem includes the funnel assembly, wherein the collection subsystem is structured and operable to align at least one receptacle with the funnel assembly and direct the one or more seeds into the at least one receptacle via the funnel assembly.

A vision inspection system includes a sorting platform having an upper surface supporting parts for inspection. An inspection station is positioned adjacent the sorting platform including an imaging device to image the parts in a field of view. A vision inspection controller receives images from the imaging device. The vision inspection controller includes an image histogram tool to pre-process the images to improve contrast of the images by redistributing lightness values of the images based on adaptive histogram equalization processing to generate enhanced images. The vision inspection controller processes the enhanced images based on an image analysis model to determine inspection results for each of the parts. The vision inspection controller has an artificial intelligence learning module operated to customize and configure the image analysis model based on the enhanced images.

Disclosed are a goods sorting system and method. The system includes a control server, a delivery robot, and a first carrying robot. The control server is configured to determine a delivery port according to a road direction of goods to be delivered, allocate the delivery robot, plan a traveling route for the delivery robot, generate a delivery instruction and send the delivery instruction to the delivery robot. The delivery robot is configured to travel to the delivery port, deliver the goods to be delivered to the delivery port. The control server is further configured to: when the number of goods collected in a target goods collection container below the delivery port is greater than or equal to a preset threshold, allocated the first carrying robot, plan a traveling route for the first carrying robot, generate a carrying instruction and send the carrying instruction to the first carrying robot. The first carrying robot is configured to travel to the target goods collection container according to the traveling route, carry the target goods collection container to a goods collection station. Further disclosed is a server and a storage medium.