A rack for automated analyser systems and provides a rack for automated analyser systems, the rack comprising a main body having an extended front side and a corresponding extended reverse side as well as at least two side walls defining at least one opening that is accessible from the main body's upper side for taking up a container for a sample that is to be processed; an upper insert that is arranged onto an upper end of the main body, wherein the upper insert has openings with a predefined diameter defining the upper surface of the rack.

Some embodiments of the disclosure provide a sample rack scheduling control method. The method includes the following steps: respectively obtaining a state of each position node on each preset delivery path, wherein the state of each position node includes an available state and an occupancy state; and for each of the delivery paths, if a target position node on the delivery path and position nodes between the target position node and a start position node all are in the available state, marking the target position node on the delivery path and the position nodes between the start position node and the target position node all as the occupancy state, and controlling a current sample rack at the start position node to move to the target position node. The present disclosure further provides a sample rack scheduling control system and a medical detection device.

Disclosed is a control method for a test system including a smear imaging unit configured to image a smear of a specimen, the control method including: preparing a plurality of the smears; sequentially storing, in a storing container capable of storing therein a plurality of the smears, the smears having been prepared; and transporting, when information about a standby situation for imaging processing by the smear imaging unit satisfies a predetermined condition, the storing container that stores therein the smears to the smear imaging unit regardless of the number of the smears stored in the storing container.

A test tube rack of an analyzer pipeline includes multiple test tube holders for holding test tubes. The test tube rack of an analyzer pipeline comprises a light blocker configured at a side wall of the test tube rack and across multiple test tube holders. A second feature area is on the light blocker between two adjacent test tube holders, a first feature area is between two adjacent second feature areas and a step gap with a predetermined depth is between the first feature area and a second feature area.

Systems and methods for handling a variety of sample and preparatory fluids in a rack specifically configured for compatibility with predetermined liquid handlers such as automated pipettors or multi-channel manual pipettors and set up for magnetic based sample preparation. The rack can hold all of the necessary sample and reagent vials, and present them to the pipettor in some embodiments in a way that allows for parallel operation. The rack includes slidable magnets that in some embodiments are actuatable directly by the pipettor, eliminating a layer of complexity. Combined with a suitable pipettor the magnet enabled rack supports a multistep magnetic based sample preparation capability in a high throughput manner at one station that enhances sample purity throughout magnetic separation processes.

The automated analyzer equalizes the temperature inside a reagent container storage apparatus. The automated analyzer is provided with a reagent container storage apparatus that cools a reagent container, the reagent container storage apparatus being provided with: a reagent storage chamber for storing the reagent container, the reagent storage chamber having at least one of the bottom surface and the side surface thereof cooled by a first cooling source; and a transfer member which is arranged to cover the reagent container stored in the reagent storage chamber, and which is thermally connected to the reagent storage chamber.

Disclosed is a station, for testing an analyte in a sample, enabling accurate and quick reaction and analysis of the sample and a reagent in one apparatus. To this end, the present disclosure provides a station, which is for testing a sample by means of inserting a cuvette, having a standby chamber on which a collecting member is placed, a sample chamber, a reagent chamber and a detection unit. The station comprises: a housing which has an input/output part into which a cuvette is inserted; a driving unit which is provided inside the housing, horizontally moves the cuvette, vertically moves a collecting member, reacts a sample in a sample chamber and a reagent in a reagent chamber, and injects a reaction result thereof into a detection unit; and an optical reader which is provided on the horizontal movement path of the cuvette and is for analyzing the reaction result.

A device and method for analyzing samples of liquid compositions of biological origin, particularly whole blood samples for determining, in particular, electrolytes. The device includes a frame, a sampling module, an analysis module including electrodes, a liquid product reserve module, a control module including electronic and computing devices, as well as a network of fluid connections.

An analysis method of an automatic analyzer is provided. The automatic analyzer includes: an insertion unit into which a rack is inserted; a transport line that transports the rack; a detection unit that detects a rack identifier from a rack or an attribute from a sample container which accommodates therein a sample as an object to be examined and which is mounted on a rack; an analysis module that includes a light source and a spectrometer which measures a measurement value to analyze a sample; a rack standby unit in which a rack stands by; and, a rack recovery unit that recovers a rack. In the automatic analyzer, a rack stands by in the rack standby unit until a measurement result in the analysis module is output; and is then recovered to the rack recovery unit. The analysis method includes: a step of transporting a rack from the rack insertion unit to the transport line, making the transported rack stand by until a measurement result in the analysis module is output, and then recovering the rack to the rack recovery; a step of detecting an identifier from the rack or an attribute from a sample container accommodating a sample and mounted on the rack; and a step of, when a rack transported subsequent to the rack of interest is transported from the rack insertion unit to the transport line, recovering the subsequent rack to the rack recovery unit without standing by in the rack standby unit.

A method for reading machine-readable labels on a plurality of sample receptacles held by a sample rack. The sample rack is moved between first and second positions within a housing and a label reader is activated at each of a plurality of predetermined position between the first and second positions to read the machine-readable label of each of the plurality of sample receptacles.