There is provided a microparticle sorting method including a procedure of collecting a microparticle in a fluid that flows through a main channel in a branch channel that is in communication with the main channel by generating a negative pressure in the branch channel. In the procedure, a flow of a fluid is formed that flows toward a side of the main channel from a side of the branch channel at a communication opening between the main channel and the branch channel.

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.

An inspection and sorting system sorts conveyed articles. The system is provided with a conveyance device, an X-ray inspection device, and a sorting device. The conveyance device conveys inspection articles. The X-ray inspection device inspects the conveyed inspection articles. The sorting device has an air sorting mechanism that sorts the conveyed inspection articles in a sorting operation. The sorting device has a sorting information receiving component, a reference signal receiving component, and a sorting mechanism control component. The sorting information receiving component receives sorting information relating to the sorting of the inspection articles based on an inspection result of the X-ray inspection device. The reference signal receiving component receives a fixed-interval reference signal relating to the conveyance by the conveyance device. The sorting mechanism control component controls the air sorting mechanism to execute the sorting operation based on the sorting information at a timing adjusted by the reference signal.

The present invention relates to a photoelectric coal and gangue sorting device and a sorting method therefor. The device comprises a support frame, a coal and gangue separation screen body, a sealing upper cover, a sieving mechanism, a driving mechanism, a separating and conveying mechanism, a positioning plate and a sorting unit; the coal and gangue separation screen body, on the top of which is provided with the sealing upper cover and inside of which is provided with the separating and conveying mechanism, is fixedly installed on one side of the support frame by means of bolts; the side wall of the positioning plate, which is arranged above the separating and conveying mechanism, is fixed to the inner wall of the coal and gangue separation screen body by means of spot welding.

The present invention relates to a photoelectric coal and gangue sorting device and a sorting method therefor. The device comprises a support frame, a coal and gangue separation screen body, a sealing upper cover, a sieving mechanism, a driving mechanism, a separating and conveying mechanism, a positioning plate and a sorting unit; the coal and gangue separation screen body, on the top of which is provided with the sealing upper cover and inside of which is provided with the separating and conveying mechanism, is fixedly installed on one side of the support frame by means of bolts; the side wall of the positioning plate, which is arranged above the separating and conveying mechanism, is fixed to the inner wall of the coal and gangue separation screen body by means of spot welding.

There is provided a microparticle sorting method including a procedure of collecting a microparticle in a fluid that flows through a main channel in a branch channel that is in communication with the main channel by generating a negative pressure in the branch channel. In the procedure, a flow of a fluid is formed that flows toward a side of the main channel from a side of the branch channel at a communication opening between the main channel and the branch channel.

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.

An apparatus for detecting matter comprises bulk feeding means configured for feeding a plurality of objects into a detecting region; at least one light source having a focusing element and being configured for illuminating at least one object moving in an object plane in the detecting region; and a first light-analyzing apparatus arranged to sense light that has been transmitted through the object. In the associated method, the object is caused to move in the plane and the object is illuminated with incident light. Light that has been transmitted through the object and is falling in a measuring plane is detected, and an object-specific parameter based on the detected transmitted light is determined.

A seed sorting system for sorting seeds includes a seed transfer station configured to move seeds through the system. An imaging assembly includes an x-ray camera configured to acquire x-ray images of the seeds as the seeds move through the system. The x-ray camera is configured to produce high quality images at high line scan rates to accommodate a speed and width at which the seeds are moved by the seed transfer station through the system. A sorting assembly is configured to sort the seeds into separate bins based on the acquired x-ray images of the seeds.

A particle sorting apparatus is provided. The particle sorting apparatus includes a first detector of a first scatter channel to detect a first light scatter generated by a particle flowing in a flow channel of a fluid sample and passing through a first laser beam, and a second detector of a second scatter channel to detect a second light scatter generated by the particle flowing in the flow channel of the fluid sample and passing through a second laser beam. The particle sorting apparatus also includes circuitry configured to output a first scatter pulse information and a first detection time of the first light scatter channel, a second scatter pulse information and a second detection time of the second light scatter channel. The first laser beam and the second laser beam are irradiated to the particle in different positions of the flow channel.