A soil fractionation system can include a plurality of sample racks propelled by a drive system. Each sample rack can include a sample tube for holding a soil sample and a filter cup for receiving an extracted fraction of the soil sample. An extractor module of the fractionation system can include an extractor assembly and a filter assembly. A control system can control the relative positioning of the plurality of sample racks via the drive system, the relative movement between the extractor assembly and the sample tube, and the relative movement between the filter assembly and the filter cup.

A configurable washing arrangement (176) washes away at least unreacted components (230, 630) of patient samples (224, 624) from a reaction cell (220, 320) with a multiple number of wash actions (206, 210, 606). The configurable washing arrangement is suitable for use with an immunoassay diagnostic system (100) and washes the reaction cell within a predetermined timed sequence (Tww). The number of the wash actions correspond with an assay type of a plurality of assay types (200, 600). The various number of wash actions may be selected without compromising overall process speed. The immunoassay diagnostic system is configured to perform the plurality of the assay types and thereby detect analytes (244, 644) in patient samples (224, 624) by at least combining each of the patient samples with at least one reagent (216, 232, 616) in the reaction cell.

An automatic analysis device and method having a BF separation process, wherein the width in a container conveyance direction of a surface facing a reaction container of a magnet for preliminary magnetic collection of a first magnetic generation part (32p) is set to have a length including a region for housing a liquid sample of the reaction container conveyed to a magnetic collection position of the first magnetic generation part. An end in the container conveyance direction of a surface facing the reaction container of a magnet for regular magnetic collection of a second magnetic generation part (32m) is designed to be close to the center of the region for housing the liquid sample of the reaction container conveyed to a magnetic collection position of the second magnetic generation part.

A reagent filling device and a sample analyzer with the reagent filling device. The reagent filling device includes a base, a horizontal rotation component, a vertical lifting component and a cantilever component, wherein, the horizontal rotation component is connected with the base, the vertical lifting component moves in a vertical direction relative to the base, the vertical lifting component drives the cantilever component to move along the vertical direction, the cantilever component is rotatably arranged relative to the vertical lifting component, there are a plurality of cantilever components, the cantilever component includes a cantilever body, a length of the cantilever body of at least one cantilever component is greater than a length of the cantilever body of each of the rest cantilever components, and the cantilever component is configured to add a reagent in a reagent disc to a reaction cup in a reaction disc.

The invention relates to a transport unit for sample containers which enclose samples to be analysed by an automatic diagnosis unit, the unit comprising: a transportation route (10) of racks (3) of samples, said route (10) extending according to a first direction (A), said route comprising a first end (102) adapted to receive a rack of samples from a first device and comprising a second end (101) adapted to transmit a rack of samples to a second device; a mobile platter (15) comprising a positioning surface extending in a plane; an analysis zone (13) arranged inside the positioning surface, and a waiting zone (12) arranged inside the positioning surface, the analysis zone (13) and the waiting zone (12) being both adapted to receive a rack (3) of samples and being both offset from the transportation route (10); a rack slider (14) configured to move a rack (3) of samples between the transportation route (10) and the waiting zone (12).

A sample processing and detecting kit with a material transfer structure comprises a kit body defined by an outer shell. A top outer shell of the kit body comprises an opening-and-closing sample port. An inner side of the kit body is disposed with a material circular plate holder and a middle of the material circular plate holder is disposed with a circular hole. A waste liquid storage chamber, a first lock groove, a second lock groove, and a sealing hole are arranged on the material circular plate holder at a periphery of the circular hole. A sample processing plastic tube member is hermitically disposed in the first lock groove. A detection reaction plastic tube member is hermetically disposed in the second lock groove.

A mechanism (10) for an automated Karl Fischer (KF) titration system (1) includes a support console (6), a first vertical guide rail element (11), solidly attached to the support console, and a carriage unit (12), slidably constrained to the first vertical guide rail element, allowing the carriage unit a first degree of linear vertical mobility relative to the support console. The carriage unit holds a vial lift unit (13) with a lift platform (14) for a sample vial (18). The carriage unit, in a downward movement phase, lowers the lift platform from a starting position into an oven cavity of the titration system. A subsequent upward movement phase raises the lift platform to the starting position. A second vertical guide rail element, solidly connected to the lift platform and slidably constrained to the carriage unit, enables a second degree of linear vertical mobility of the lift platform.

An automatic analysis device and method having a BF separation process, wherein the width in a container conveyance direction of a surface facing a reaction container of a magnet for preliminary magnetic collection of a first magnetic generation part (32p) is set to have a length including a region for housing a liquid sample of the reaction container conveyed to a magnetic collection position of the first magnetic generation part. An end in the container conveyance direction of a surface facing the reaction container of a magnet for regular magnetic collection of a second magnetic generation part (32m) is designed to be close to the center of the region for housing the liquid sample of the reaction container conveyed to a magnetic collection position of the second magnetic generation part.

A sample injector for chromatography 10 where air or moisture can be prevented from getting mixed in when a sample is injected is provided with a syringe 11, a syringe drive unit 13, a turret 12 in which sample vials 4 are placed, a turret drive unit 14, and a control unit 30 that controls the syringe and turret drive units 13 and 14. The configuration includes a housing 15 having a gas introduction port 15a and a gas discharge port 15b that communicate with the inner space, where the syringe 11 sucks a sample from a sample vial 4, the sucked sample is injected into the sample vaporizing chamber 23 in a chromatograph 20, and a predetermined gas is introduced through the gas introduction port 15a, and at the same time, a predetermined gas is discharged through the gas discharge port 15b when a sample is analyzed.

A detection device using a lateral flow strip for detection and a detection method thereof are provided, which relates to the technical field of a detection device using a lateral flow strip. An upper rotor, a middle rotor and a lower rotor are respectively provided with upper paddle(s), middle paddle(s) and lower paddle(s) along respective circumferential directions. Each upper paddle is provided with a test tube with openings at both ends thereof for placing the lateral flow strip. The middle paddle blocks a bottom one of the openings of the test tube. Each lower paddle is provided with a sample tube for placing sample solution. The bottom opening of the test tube is opposite to a top opening of the sample tube up and down.