Sortable tracking objects that can be associated with item containers and items for tracking and organization.

Embodiments of the present disclosure provide an interrogation device that is operable to apply one or more source signals to one or more coils surrounding a volume, where a material is disposed within the volume. Each of the one or more source signals may excite one of the one or more coils, and the behavior of each the one or more coils responsive to the exciting may be monitored. One or more parameters may be determined based on the behavior of each the one or more coils, and the one or more parameters may be utilized to generate a signature for the material within the volume. The signature may be compared to one or more signatures of known materials to identify the material within the volume.

Embodiments of the present disclosure provide an interrogation device that is operable to apply one or more source signals to one or more coils surrounding a volume, where a material is disposed within the volume. Each of the one or more source signals may excite one of the one or more coils, and the behavior of each the one or more coils responsive to the exciting may be monitored. One or more parameters may be determined based on the behavior of each the one or more coils, and the one or more parameters may be utilized to generate a signature for the material within the volume. The signature may be compared to one or more signatures of known materials to identify the material within the volume.

Discussed is a a process automation system including: a cell transferor configured to transfer battery cells; a cell inspector configured to measure an open circuit voltage of each battery cell in units of a preset number of battery cells and to sort out qualified battery cells and defective battery cells; a frame transferor configured to transfer module frames of a battery module to insert the qualified battery cells; a cell discharger configured to load and discharge the defective battery cells; and a gripper configured to pick up one or more battery cells from any one device among the cell transferor, the cell inspector, the frame transferor, and the cell discharger, and transport the one or more battery cells to another device.

A method of inspecting metallic container components (10) provides indexing a container component (10) produced from a metallic material into axial alignment with a probe (110). The probe (110) has a coil (176) produced from an electrical conductor. An alternating current (183) is applied to the coil (176) wherein a first magnetic field (184) is generated. An eddy current (188) develops in the container component (10) in response to the first magnetic field (184). A second magnetic field (192) is generated in response to the eddy current (188). Changes in an impedance amplitude and phase angle in the coil (176) are measured. A determination of the fitness for use of the container component (10) is made based on the measured changes in the impedance amplitude and phase angle in the coil (176).

A material analysis and separation system equipped with a conveyor belt, X-ray source, X-ray detector, which has the X-ray source located in such a way that X rays penetrate the measured material over the entire width of the conveyor belt, and the radiation detectors consist of multiple radiation sensors located on the entire width of the belt, while the sensor system is equipped with devices that allow for data processing in dual energy (DE Dual Energy) or multi-energy (ME Multi Energy) X-ray analysis range. The system also includes a computer unit that controls the system rejecting material particles falling below the separation criterion threshold and devices receiving separated material fractions. The X-ray analysis system is equipped with a hyper-spectral analysis system in the range of infra-red radiation using a source of infra-red radiation (15) and hyper-spectral camera (19).

An illustrative embodiment disclosed herein is a method including receiving, by a waste diversion system and from a source, waste materials, inserting, by the waste diversion system and into the waste materials, one or more markers, generating, by the waste diversion system, finished goods including a portion of the waste materials, and detecting, by the waste diversion system, a portion of the one or more markers corresponding to the portion of the waste materials in the finished goods.

An apparatus and a method for separating or sorting parts are described. For example, an apparatus can include a fluidic section that comprises an input section. The fluidic section can be configured to receive a fluid including a plurality of parts at the input section. The fluidic section can be configured to receive the fluid at an inlet port of the fluidic section. The fluidic section can include at least two branches extending from the input section, and each of these at least two branches can have an outlet through which the fluid or part of the fluid can be routed. The apparatus can include a set of sensors configured to capture information about the plurality of parts in the fluidic section. The apparatus can further include a set of actuators configured to effect, based on the information, a change in a movement of a set of parts from the plurality of parts such that the set of parts is distributed via the fluid to at least one of the at least two branches.

A method of analyzing minerals received within a mining shovel bucket includes collecting data associated with ore received in the bucket, where the bucket includes at least one active sensor, where the ore includes one or more mineral, and where the ore is within a field of the active sensor. The method further includes determining a content of the minerals using the data, transmitting information relating to the content of the minerals to a decision support system, and sorting or processing the ore based on an output of the decision support system. Collecting data associated with the ores may include generating source signals, applying the source signals to the active sensor, collecting a response from the active sensor, and comparing the response with a reference or threshold. Other features are disclosed.

A method of analyzing minerals received within a mining shovel bucket includes collecting data associated with ore received in the bucket, where the bucket includes at least one active sensor, where the ore includes one or more mineral, and where the ore is within a field of the active sensor. The method further includes determining a content of the minerals using the data, transmitting information relating to the content of the minerals to a decision support system, and sorting or processing the ore based on an output of the decision support system. Collecting data associated with the ores may include generating source signals, applying the source signals to the active sensor, collecting a response from the active sensor, and comparing the response with a reference or threshold. Other features are disclosed.