Disclosed are high-throughput vessel receiving systems and methods of receiving sample vessels, such as samples stored in test tubes. A system for receiving a plurality of individual vessels that each contains a sample, and systems and apparatus for guiding, reorienting, collecting, and transporting a plurality of articles, including vessels, are disclosed.

Disclosed are high-throughput vessel sorting systems and methods of sorting sample vessels, such as samples stored in test tubes. A system for sorting a plurality of individual vessels that each contains a sample is disclosed.

Disclosed are high-throughput vessel supply systems and methods of supplying sample vessels, such as samples stored in test tubes. A system for supplying a plurality of individual vessels that each contains a sample is disclosed.

A sample rack moving mechanism is provided for removing a sample rack loaded with one or more sample containers from a temporary storing section, and returning the sample rack loaded with the sample containers holding the tested sample to the temporary storing section. The sample rack moving mechanism may include a drive element, a cam driven by the drive element to rotate and having a curve contour, a cam follower moving following the outer contour of the cam, a guide groove corresponding to the temporary storing section, having a bottom plane of the same height as a support plane of the temporary storing section for supporting the sample rack, and capable of moving the sample rack, and a support element driven by the cam follower to move upward and downward and driving the sample rack to horizontally move between the temporary storing section and the guide groove.

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.

A fully-automatic immunofluorescence quantitative analyzing apparatus and detection method belong to the field of quantitative immunofluorescence analysis and detection. The immunity quantitative analyzing apparatus includes a support baseplate, a reagent strip storage and automatic loading module, a cuvette ring module, a detection module, a sample module, a sample dispensing module, a washing module and a control system, the reagent strip storage and automatic loading module, the cuvette ring module, the detection module, the sample module, the sample dispensing module, the washing module being sequentially arranged on the support baseplate. The reagent strip storage and automatic loading module provides a reagent strip for the cuvette ring module, and the sample dispensing module dispenses the sample on the sample module to the cuvette ring module and performs a reaction, and the sample enters the detection module to complete the detection after the reaction is complete.

A sample container handling device is presented. The device comprises a linear transport unit and a release unit comprising a release blade segment. The release blade segment is rotated in a constant rotational direction.

A sample transport method, applied to a test instrument including a conveyor belt, and a loading platform and a grab position sequentially disposed along a transport direction of the conveyor belt, wherein a plurality of sample holder transport positions are disposed on the conveyor belt; the method including: pushing a first sample holder from the loading platform to a sample holder transport position of the conveyor; when a sample position on the first sample holder moves to the grab position, determining whether the sample position moved the grab position is a target sample position; if so, then determining whether all samples positions on the first sample holder before the target sample holder other than a predetermined number of sample positions have completed testing, wherein the predetermined number is sample position number corresponding to a delay time in outputting information indicating whether a sample needs to be retested.

A digital slide scanning apparatus slide rack carousel allows continuous loading and unloading of slide racks into the carousel while the digital slide scanning apparatus is simultaneously digitizing glass slides. The slide rack carousel includes a base having an interior portion of its upper surface at an angle. The slide rack carousel also includes plural rack spacers extending upward from the base and adjacent rack spacers define a rack slot. Each rack spacer also includes a rack stopper on each side such that adjacent rack spacers have rack stoppers facing each other. The rack stoppers prevent a slide rack from moving further toward the center of the carousel than desired.

A sample rack moving mechanism is provided for removing a sample rack loaded with one or more sample containers from a temporary storing section, and returning the sample rack loaded with the sample containers holding the tested sample to the temporary storing section. The sample rack moving mechanism may include a drive element, a cam driven by the drive element to rotate and having a curve contour, a cam follower moving following the outer contour of the cam, a guide groove corresponding to the temporary storing section, having a bottom plane of the same height as a support plane of the temporary storing section for supporting the sample rack, and capable of moving the sample rack, and a support element driven by the cam follower to move upward and downward and driving the sample rack to horizontally move between the temporary storing section and the guide groove.