The present disclosure relates to systems, non-transitory computer-readable media, and methods for analyzing and sorting batteries according to battery classifications. In particular, in one or more embodiments, the disclosed systems scan a target battery with a plurality of sensors and analyze signals of the plurality of sensors utilizing a classifier model to determine a battery classification for the target battery. Also, in some embodiments, the disclosed systems indicate the predicted battery classification to a battery sorting mechanism for sorting the target battery. Additional mechanisms and related methods for automated classification and sorting of batteries are disclosed.

The present disclosure relates to systems, non-transitory computer-readable media, and methods for analyzing and sorting batteries according to battery classifications. In particular, in one or more embodiments, the disclosed systems scan a target battery with a plurality of sensors and analyze signals of the plurality of sensors utilizing a classifier model to determine a battery classification for the target battery. Also, in some embodiments, the disclosed systems indicate the predicted battery classification to a battery sorting mechanism for sorting the target battery. Additional mechanisms and related methods for automated classification and sorting of batteries are disclosed.

Embodiments herein disclose an object screening system and method. The object screening system includes a scanner grid configured to parallelly scan a plurality of objects received via a receiving conveyor line, where the scanner grid includes a plurality of scanners arranged in a pre-determined configuration selected to substantially reduce a scanning time of the plurality of objects. A distribution module configured to determine a distribution pattern for the plurality of objects received via the receiving conveyor line and to selectively direct each of the plurality of objects to respective input conveyor lines of one or more scanners in accordance with the distribution pattern. A processing unit configured to receive a data package corresponding to each of the scanned objects from the one or more scanners and to process the data package to identify a risk category of the objects based on the data package.

Images depicting items in a waste flow on a conveyor belt are provided to two analysis systems. The first system processes images to decode digital watermark payload data found on certain of the items (e.g., plastic containers). This payload data is used to look up corresponding attribute metadata for the items in a database, such as the type of plastic in each item, and whether the item was used as a food container or not. The second analysis system can be a spectroscopy system that determines the type of plastic in each item by its absorption characteristics. When the two systems conflict in identifying the plastic type, a sorting logic processor applies a rule set to arbitrate the conflict and determine which plastic type is most likely. The item is then sorted into one of several different bins depending on a combination of the final plastic identification, and whether the item was used as a food container or not. A variety of other features and arrangements are also detailed.

When a granular object is determined to have to be sorted out two or more times in two or more of sort-out necessity/unnecessity determination results determined by a determination portion, a sort-out signal setting portion of an optical sorting apparatus sets a sort-out actuation signal that contains information for actuating an ejector when the granular object advancing in the air passes through a sorting region based on a combination of the sort-out necessity/unnecessity determination results from a predetermined signal setting table.

A method for discriminating a sorting target includes transferring the sorting target, imaging the sorting target during the transferring, and discriminating the sorting target based on imaging information acquired in the imaging. The imaging information includes adjacency information between sorting targets, and classification information of the sorting target.

Differences in x-ray absorption coefficients and ash content are used to process coal waste and concentrate rare earth elements (REE) found in coal seams. A method for processing the coal waste includes receiving, by a detector, at least one collimated x-ray beam from an x-ray source that has been passed through a sample of coal waste; determining measurements of at least one x-ray absorption characteristic of the sample based on the received at least one collimated x-ray beam; and identifying a first region in the sample having a concentration of rare earth elements based on the measured x-ray absorption characteristic.

A particle sorting apparatus is provided. The particle sorting apparatus includes a first light irradiating unit including a first mirror and a first light source for irradiating a first light to particles flowing through a flow path at a first position; a second light irradiating unit including a second mirror and a second light source configured to irradiate a second light to particles flowing through the flow path at a second position which is different from the first position; a light detecting unit is configured to detect a light emitted from the particles; a sorting unit; and a sorting control unit configured to control sorting of the particles based on data of the particles detected at the light detecting unit and an arrival time associated with a time difference between a light from the first light irradiating unit and a light from the second light irradiating unit; wherein the flow path and the sorting unit are provided within a microchip.

A golf ball sorting system has a ball feeder configured to transport a plurality of golf balls. At least some of the golf balls have a conductive marking pattern that is not visible to an observer because the marking pattern is covered by at least one other layer of the golf ball. A detection system receives the golf balls, inspects the golf balls, and outputs a detection result. A sorting system receives the detection result and sorts the plurality of golf balls based on the detection result to separate the plurality of golf balls into at least three groups, including a first category of golf balls that do not have the marking pattern, a second category of golf balls that have a first type of the marking pattern, and a third category of golf balls that have a second type of the marking pattern.

A combined weighing system 1 includes a first X-ray inspection device 20, a combined weighing device 40, a bag making and packaging device 50, a weight inspection device 60, a second X-ray inspection device 70, and a management device 90 that manages each device. The management device 90 revises a weight conversion table of the first X-ray inspection device 20 and a correction value of the combined weighing device 40 based on an average value of weights of products B, which is calculated from a result of inspection over a certain time period in the weight inspection device 60.